Method for driving semiconductor devices

JP2026086491A5Pending Publication Date: 2026-07-07SEMICON ENERGY LAB CO LTD

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
SEMICON ENERGY LAB CO LTD
Filing Date
2026-01-27
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing organic EL display devices require high voltages for operation, and variations in transistor threshold voltages can degrade display quality, necessitating improved driving methods to enhance miniaturization, display quality, color reproducibility, and reduce power consumption.

Method used

A semiconductor device comprising specific transistor configurations with back gates, capacitors, and switches, utilizing metal oxide transistors, and a driving method that controls transistor states to stabilize voltage thresholds, including processes that correct variations in transistor threshold voltages.

Benefits of technology

The solution provides a miniaturized, high-definition, and highly reliable display device with improved display quality and reduced power consumption, achieving high color reproducibility.

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Abstract

The present invention provides a novel semiconductor device and a method for driving such a semiconductor device. [Solution] A semiconductor device and a method for driving a semiconductor device, comprising first and second transistors, first to fifth switches, first to third capacitors, and a display element, wherein the first transistor has a back gate, the gate of the first transistor is electrically connected to the first switch, the gate of the first transistor has a second switch and a first capacitor between the gate of the first transistor and the source of the first transistor, the back gate of the first transistor is electrically connected to the third switch, the back gate of the first transistor has a second capacitor between the back gate of the first transistor and the source of the first transistor, the source of the first transistor is electrically connected to the fourth switch and the drain of the second transistor, the gate of the second transistor is electrically connected to the fifth switch, the gate of the second transistor has a third capacitor between the gate of the second transistor and the source of the second transistor, and the source of the second transistor is electrically connected to a display element.
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Description

[Technical Field]

[0001] One aspect of the present invention relates to a semiconductor device and a method for driving a semiconductor device.

[0002] It should be noted that one aspect of the present invention is not limited to the above-mentioned technical field. Examples of technical fields of one aspect of the present invention disclosed herein include semiconductor devices, display devices, light-emitting devices, energy storage devices, memory devices, electronic devices, lighting devices, input devices, input / output devices, methods for driving them, or methods for manufacturing them.

[0003] In this specification, a semiconductor device refers to a device that utilizes semiconductor properties, such as a circuit containing semiconductor elements (e.g., transistors, diodes, photodiodes, etc.) or a device having such a circuit. It also refers to any device that can function by utilizing semiconductor properties. For example, integrated circuits, chips equipped with integrated circuits, or electronic components with chips housed in a package are examples of semiconductor devices. Furthermore, for example, memory devices, display devices, light-emitting devices, lighting devices, or electronic devices are themselves semiconductor devices and may also contain semiconductor devices. [Background technology]

[0004] For example, there is a demand for display devices applicable to XR applications such as VR (Virtual Reality) or AR (Augmented Reality). Specifically, to enhance realism and immersion, such display devices are desired to have features such as high resolution and high color reproduction.

[0005] Examples of devices to which this display device can be applied include liquid crystal displays, organic EL (Electro Luminescence) elements, and light-emitting devices equipped with light-emitting elements such as light-emitting diodes (LEDs).

[0006] For example, the basic structure of an organic EL device is one in which a layer containing a light-emitting organic compound is sandwiched between a pair of electrodes. By applying a voltage to this device, light emission can be obtained from the light-emitting organic compound. A display device to which such an organic EL device is applied does not require a backlight, which was necessary for, for example, a liquid crystal display device, etc., and thus can realize a display device that is thin, lightweight, has high contrast, and consumes low power. In addition, since the response speed of the organic EL device is fast, a display device suitable for displaying fast-moving images can be realized. For example, an example of a display device using an organic EL device is described in Patent Document 1.

[0007] Also, in Patent Document 2, a circuit configuration is disclosed that corrects the variation in the threshold voltage of transistors for each pixel in a pixel circuit that controls the light emission luminance of an organic EL device, thereby improving the display quality of the display device.

Prior Art Documents

Patent Documents

[0008]

Patent Document 1

Patent Document 2

Summary of the Invention

Problems to be Solved by the Invention

[0009] On the other hand, depending on the configuration of the organic EL element, a high voltage may be required to drive the organic EL element. In order to drive such an organic EL element, it was necessary to provide a power source for generating a high voltage. Further, the current flowing through the organic EL element is controlled by, for example, a driving transistor. Since the driving transistor is provided for each pixel, if there is variation in the threshold voltage of each driving transistor, the display quality of the display device including the organic EL element may deteriorate. As a means for improving the display quality of the display device, for example, a correction period for correcting the variation in the threshold voltage of each transistor included in each pixel during the driving period of the display device can be provided.

[0010] One aspect of the present invention aims to provide a miniaturized semiconductor device or display device. Or, one aspect of the present invention aims to provide a semiconductor device or display device with improved display quality. Or, one aspect of the present invention aims to provide a semiconductor device or display device in which high color reproducibility is achieved. Or, one aspect of the present invention aims to provide a high-definition semiconductor device or display device. Or, one aspect of the present invention aims to provide a highly reliable semiconductor device or display device. Or, one aspect of the present invention aims to provide a semiconductor device or display device with reduced power consumption. Or, one aspect of the present invention aims to provide a novel semiconductor device or display device.

[0011] Note that the description of these problems does not prevent the existence of other problems. Note that one aspect of the present invention does not need to solve all of these problems. Note that other problems can be extracted from the descriptions in the specification, drawings, claims, etc.

Means for Solving the Problems

[0012] (1) One aspect of the present invention is a semiconductor device comprising first and second transistors, first to fifth switches, first to third capacitors, and a display element, wherein the first transistor has a back gate, the gate of the first transistor is electrically connected to a first switch, a second switch and a first capacitor are provided between the gate of the first transistor and the source of the first transistor, the back gate of the first transistor is electrically connected to a third switch, a second capacitor is provided between the back gate of the first transistor and the source of the first transistor, the source of the first transistor is electrically connected to a fourth switch and the drain of the second transistor, the gate of the second transistor is electrically connected to a fifth switch, a third capacitor is provided between the gate of the second transistor and the source of the second transistor, and the source of the second transistor is electrically connected to a display element.

[0013] (2) Furthermore, in (1) above, the first switch may have the function of making the connection between the first wiring and the gate of the first transistor conductive or non-conductive, the second switch may have the function of making the connection between the gate of the first transistor and the source of the first transistor conductive or non-conductive, the third switch may have the function of making the connection between the second wiring and the back gate of the first transistor conductive or non-conductive, the fourth switch may have the function of making the connection between the third wiring and the source of the first transistor conductive or non-conductive, and the fifth switch may have the function of making the connection between the fourth wiring and the gate of the second transistor conductive or non-conductive.

[0014] (3) Furthermore, in (1) or (2) above, the first to fifth switches may each be transistors.

[0015] (4) Furthermore, in any one of (1) to (3) above, it is preferable that at least one of the first transistor and the second transistor is a transistor in which a metal oxide is included in the semiconductor layer in which the channel is formed.

[0016] (5) Furthermore, in (4) above, it is preferable that the metal oxide contains at least one of indium and zinc.

[0017] (6) Furthermore, in any one of the above (1) to (5), for example, a tandem-structured organic EL element can be used as the display element.

[0018] (7) One aspect of the present invention is a method for driving a semiconductor device, comprising first and second transistors, first to fifth switches, first to third capacitors, and a display element, wherein the first transistor has a back gate, the gate of the first transistor is electrically connected to a first switch, a second switch and a first capacitor are provided between the gate of the first transistor and the source of the first transistor, the back gate of the first transistor is electrically connected to a third switch, a second capacitor is provided between the back gate of the first transistor and the source of the first transistor, the source of the first transistor is electrically connected to a fourth switch and the drain of the second transistor, the gate of the second transistor is electrically connected to a fifth switch, a third capacitor is provided between the gate of the second transistor and the source of the second transistor, and the source of the second transistor is electrically connected to a display element, the method comprising first to fourth processes, the first process is This is a method for driving a semiconductor device, comprising: supplying a first potential to the source of the first transistor via a fourth switch and to the gate of the first transistor via a second switch, supplying a second potential higher than the first potential to the back gate of the first transistor via a third switch; supplying a third potential to the gate of the first transistor via a first switch and to the source of the first transistor via a fourth switch; supplying a potential to make the second transistor conduct via a fifth switch to the gate of the second transistor via a fifth switch; supplying a potential to make the second transistor non-conductive via a fifth switch to the gate of the second transistor via a fifth switch; starting the first process after the start of the fourth process, starting the third process after the end of the fourth process, ending the first process before the start of the third process, starting the second process after the end of the first process, and starting the fourth process after the end of the second process and after the end of the third process.

[0019] (8) Furthermore, in (7) above, the first switch may have the function of making the connection between the first wiring and the gate of the first transistor conductive or non-conductive, the second switch may have the function of making the connection between the gate of the first transistor and the source of the first transistor conductive or non-conductive, the third switch may have the function of making the connection between the second wiring and the back gate of the first transistor conductive or non-conductive, the fourth switch may have the function of making the connection between the third wiring and the source of the first transistor conductive or non-conductive, and the fifth switch may have the function of making the connection between the fourth wiring and the gate of the second transistor conductive or non-conductive.

[0020] (9) Furthermore, in (7) or (8) above, the first to fifth switches may each be transistors.

[0021] (10) Furthermore, in any one of (7) to (9) above, it is preferable that at least one of the first transistor and the second transistor is a transistor in which a metal oxide is included in the semiconductor layer in which the channel is formed.

[0022] (11) Furthermore, in (10) above, it is preferable that the metal oxide contains at least one of indium and zinc.

[0023] (12) Furthermore, in any one of the above (7) to (11), for example, a tandem-structured organic EL element can be used as the display element.

[0024] (13) One aspect of the present invention is a method for driving a semiconductor device comprising a transistor, a switch, and a signal line, wherein the source of the transistor is electrically connected to one terminal of the switch, and the method comprises first to fourth processes: the first process supplies a first potential to the source of the transistor and to the gate of the transistor; the second process supplies a first potential to the source of the transistor and to the potential of the signal line to the gate of the transistor; the third process makes the switch conductive; the fourth process makes the switch non-conductive; after the start of the fourth process, the potential of the signal line and the first potential are compared; if the potential of the signal line and the first potential are the same potential, the first process is started; before the start of the third process, the first process is terminated; after the end of the first process, the second process is started; if the potential of the signal line and the first potential are not the same potential, the second process is started; after the end of the fourth process, the third process is started; and after the end of both the second and third processes, the fourth process is started.

[0025] (14) One aspect of the present invention is a method for driving a semiconductor device, comprising a transistor, a switch, and a signal line, wherein the source of the transistor is electrically connected to one terminal of the switch, and the method comprises first to fourth processes, wherein the first process supplies a first potential to the source of the transistor and to the gate of the transistor, and supplies the same potential as the first potential to the signal line, the second process supplies a first potential to the source of the transistor and to the potential of the signal line to the gate of the transistor, the third process makes the switch conductive, the fourth process makes the switch non-conductive, the first process is started after the start of the fourth process, the first process is ended before the start of the third process, the second process is started after the end of the first process, the third process is started after the end of the fourth process, and the fourth process is started after the end of both the second and third processes.

[0026] (15) One aspect of the present invention is a method for driving a semiconductor device, comprising a transistor, a switch, and a signal line, wherein the source of the transistor is electrically connected to one terminal of the switch, and the method comprises first to fourth processes: the first process supplies a first potential to the source of the transistor and to the gate of the transistor, and puts the signal line into a floating state; the second process supplies a first potential to the source of the transistor and to the potential of the signal line to the gate of the transistor; the third process puts the switch into a conductive state; the fourth process puts the switch into a non-conductive state; the first process is started after the start of the fourth process, the first process is ended before the start of the third process, the second process is started after the end of the first process, the third process is started after the end of the fourth process, and the fourth process is started after the end of both the second and third processes. [Effects of the Invention]

[0027] One aspect of the present invention can provide a miniaturized semiconductor device or display device. Alternatively, one aspect of the present invention can provide a semiconductor device or display device with improved display quality. Alternatively, one aspect of the present invention can provide a semiconductor device or display device with high color reproducibility. Alternatively, one aspect of the present invention can provide a high-definition semiconductor device or display device. Alternatively, one aspect of the present invention can provide a highly reliable semiconductor device or display device. Alternatively, one aspect of the present invention can provide a semiconductor device or display device with reduced power consumption. Alternatively, one aspect of the present invention can provide a novel semiconductor device or display device.

[0028] Furthermore, the description of these effects does not preclude the existence of other effects. Moreover, one aspect of the present invention does not necessarily have to possess all of these effects. Other effects can be extracted from the description in the specification, drawings, claims, etc. [Brief explanation of the drawing]

[0029] [Figure 1] Figure 1 is a diagram illustrating a semiconductor device. [Figure 2]Figure 2 is a diagram illustrating a semiconductor device. [Figure 3] Figure 3 is a diagram illustrating a semiconductor device. [Figure 4] Figure 4 is a diagram illustrating a semiconductor device. [Figure 5] Figure 5 is a diagram illustrating a semiconductor device. [Figure 6] Figures 6A to 6C show the circuit symbols for transistors. [Figure 7] Figure 7 is a timing chart illustrating an example of semiconductor device operation. [Figure 8] Figure 8 illustrates an example of the operation of a semiconductor device. [Figure 9] Figure 9 illustrates an example of the operation of a semiconductor device. [Figure 10] Figure 10 is a diagram illustrating an example of the operation of a semiconductor device. [Figure 11] Figure 11 illustrates an example of the operation of a semiconductor device. [Figure 12] Figure 12 illustrates an example of the operation of a semiconductor device. [Figure 13] Figure 13 illustrates an example of the operation of a semiconductor device. [Figure 14] Figure 14 is a timing chart illustrating the driving method of a semiconductor device. [Figure 15] Figure 15 is a timing chart illustrating the driving method of a semiconductor device. [Figure 16] Figure 16 is a diagram illustrating a semiconductor device. [Figure 17] Figure 17 is a timing chart illustrating the operation of a semiconductor device. [Figure 18] Figure 18 is a diagram illustrating the operation of a semiconductor device. [Figure 19] Figure 19 is a diagram illustrating the operation of a semiconductor device. [Figure 20] Figure 20 is a diagram illustrating the operation of a semiconductor device. [Figure 21] Figure 21 is a diagram illustrating the operation of a semiconductor device. [Figure 22] Figure 22 is a diagram illustrating the operation of a semiconductor device. [Figure 23] Figure 23 is a diagram illustrating the operation of a semiconductor device. [Figure 24] Figure 24 is a timing chart illustrating the driving method of a semiconductor device. [Figure 25] Figure 25 is a timing chart illustrating the driving method of a semiconductor device. [Figure 26] Figure 26 is a flowchart illustrating the method for driving a semiconductor device. [Figure 27] Figure 27A is a diagram illustrating a display device. Figures 27B to 27H illustrate examples of pixel configurations. [Figure 28] Figures 28A to 28D show examples of the configuration of a light-emitting element. [Figure 29] Figures 29A to 29D show examples of the configuration of light-emitting elements. [Figure 30] Figures 30A to 30D show examples of the configuration of a light-emitting element. [Figure 31] Figures 31A and 31B show examples of the configuration of light-emitting elements. [Figure 32] Figures 32A and 32B are perspective views of the display device. [Figure 33] Figure 33 is a cross-sectional view showing an example of a display device. [Figure 34] Figure 34 is a cross-sectional view showing an example of a display device. [Figure 35] Figure 35 is a cross-sectional view showing an example of a display device. [Figure 36] Figure 36 is a cross-sectional view showing an example of a display device. [Figure 37] Figure 37A is a top view showing an example of a transistor configuration. Figures 37B and 37C are cross-sectional views showing an example of a transistor configuration. [Figure 38] Figure 38A is a diagram illustrating the classification of crystal structures. Figure 38B is a diagram illustrating the XRD spectrum of the CAAC-IGZO film. Figure 38C is a diagram illustrating the micro-electron diffraction pattern of the CAAC-IGZO film. [Figure 39] Figures 39A to 39F illustrate an example of an electronic device. [Figure 40] Figures 40A to 40F illustrate an example of an electronic device. [Figure 41] Figures 41A and 41B illustrate an example of an electronic device. [Figure 42] Figure 42 is a diagram illustrating an example of an electronic device. [Figure 43] Figure 43 shows the process flow of a transistor. [Figure 44] Figure 44 is a schematic perspective view of a transistor. [Figure 45] Figures 45A to 45D are STEM images of the transistor and the area around it. [Figure 46] Figure 46 shows the evaluation results of the Id-Vg characteristics of the transistor. [Figure 47] Figure 47 shows the evaluation results of the Vth variation of transistors. [Figure 48] Figures 48A and 48B show the evaluation results of the Id-Vd characteristics of the transistors. [Figure 49] Figure 49 shows the evaluation results for the Vd breakdown voltage of the transistor. [Figure 50] Figure 50 shows a method for evaluating the off-current of a transistor. [Figure 51] Figure 51 shows the evaluation results of the transistor's off-current. [Figure 52] Figure 52 shows the evaluation results of the display device. [Figure 53] Figure 53 shows the evaluation results of the display device. [Figure 54] Figures 54A and 54B show the evaluation results of the chromaticity of the display device. [Modes for carrying out the invention]

[0030] The embodiments will be described below with reference to the drawings. However, the embodiments can be implemented in many different ways. Therefore, it will be easily understood by those skilled in the art that the form and details can be changed in various ways without departing from the spirit and scope. Accordingly, the present invention is not to be construed as being limited to the contents of the following embodiments.

[0031] Furthermore, where it is stated in this specification that X and Y are connected, this specification discloses the cases in which X and Y are electrically connected, functionally connected, and directly connected. Therefore, it is not limited to predetermined connection relationships, such as those shown in the figures or text, but also includes connection relationships other than those shown in the figures or text. X and Y are, respectively, objects (e.g., devices, elements, circuits, wiring, electrodes, terminals, conductive films, or layers).

[0032] One example of a case where X and Y are electrically connected is that one or more elements that enable the electrical connection between X and Y (e.g., switches, transistors, capacitive elements, inductors, resistors, diodes, display devices, light-emitting devices, or loads) can be connected between X and Y.

[0033] One example of a functional connection between X and Y is when one or more circuits that enable the functional connection between X and Y (e.g., logic circuits (e.g., inverters, NAND gates, or NOR gates), signal conversion circuits (e.g., digital-to-analog conversion circuits, analog-to-digital conversion circuits, or gamma correction circuits), potential level conversion circuits (e.g., power supply circuits (e.g., boost circuits, or buck circuits), or level shifter circuits that change the potential level of a signal), voltage sources, current sources, switching circuits, amplification circuits (e.g., circuits that can increase signal amplitude or current, such as operational amplifiers, differential amplifiers, source follower circuits, or buffer circuits), signal generation circuits, memory circuits, or control circuits) can be connected between X and Y.

[0034] Furthermore, when it is explicitly stated that X and Y are electrically connected, this includes both cases where X and Y are electrically connected (i.e., connected with another element or circuit in between) and cases where X and Y are directly connected (i.e., connected without another element or circuit in between).

[0035] Furthermore, it can be expressed as, for example, "X, Y, the source (or first terminal, etc.) and drain (or second terminal, etc.) of the transistor are electrically connected to each other, and the connection is in the order of X, the source (or first terminal, etc.) of the transistor, the drain (or second terminal, etc.) of the transistor, and Y." Alternatively, it can be expressed as, "The source (or first terminal, etc.) of the transistor is electrically connected to X, and the drain (or second terminal, etc.) of the transistor is electrically connected to Y, and X, the source (or first terminal, etc.) of the transistor, the drain (or second terminal, etc.) of the transistor, and Y are electrically connected in this order." Alternatively, it can be expressed as, "X is electrically connected to Y via the source (or first terminal, etc.) and drain (or second terminal, etc.) of the transistor, and X, the source (or first terminal, etc.) of the transistor, the drain (or second terminal, etc.) of the transistor, and Y are provided in this connection order." By using similar notation to these examples to define the order of connections in a circuit configuration, the source (or first terminal, etc.) and drain (or second terminal, etc.) of a transistor can be distinguished and their technical scope determined. Note that these notational methods are examples only and are not limited to them. Here, X and Y are objects (e.g., devices, elements, circuits, wiring, electrodes, terminals, conductive films, or layers, etc.).

[0036] Even if independent components are shown as electrically connected in a circuit diagram, a single component may possess the functions of multiple components. For example, if part of a wiring also functions as an electrode, a single conductive film possesses the functions of both the wiring and the electrode. Therefore, in this specification, "electrically connected" includes cases where a single conductive film possesses the functions of multiple components.

[0037] Furthermore, in this specification, "capacitive element" may refer to, for example, a circuit element having a capacitance value higher than 0F, a region of wiring having a capacitance value higher than 0F, parasitic capacitance, or the gate capacitance of a transistor. Therefore, in this specification, "capacitive element" is not limited to a circuit element including a pair of electrodes and a dielectric material contained between the electrodes. "Capacitive element" includes, for example, parasitic capacitance occurring between wiring, or gate capacitance occurring between one of the source or drain of a transistor and the gate. Also, terms such as "capacitive element," "parasitic capacitance," or "gate capacitance" can be replaced with terms such as "capacitance." Conversely, the term "capacitance" can be replaced with terms such as "capacitive element," "parasitic capacitance," or "gate capacitance." Furthermore, the term "pair of electrodes" in "capacitance" can be replaced with terms such as "pair of conductors," "pair of conductive regions," or "pair of regions." The capacitance value can be, for example, 0.05fF or more and 10pF or less. Alternatively, for example, it may be set to between 1 pF and 10 μF.

[0038] Furthermore, in this specification, a transistor has three terminals called the gate, source, and drain. The gate is a control terminal that controls the amount of current flowing between the source and drain. The two terminals that function as either the source or the drain are the input and output terminals of the transistor. Depending on the conductivity type of the transistor (n-channel or p-channel) and the potential difference between the three terminals of the transistor, one of the two input and output terminals becomes the source and the other becomes the drain. For this reason, in this specification, the terms "source" and "drain" can be used interchangeably. Also, in this specification, when describing the connection relationships of a transistor, the notation "one of the source or drain" (or the first electrode or first terminal) or "the other of the source or drain" (or the second electrode or second terminal) is used. Note that, depending on the structure, a transistor may have a back gate in addition to the three terminals described above. In this case, in this specification, one of the gate or back gate of the transistor may be called the first gate, and the other of the gate or back gate of the transistor may be called the second gate. Furthermore, in the same transistor, the terms "gate" and "back gate" may be interchangeable. Furthermore, if a transistor has three or more gates, in this specification, each gate may be referred to as, for example, the first gate, the second gate, or the third gate.

[0039] Furthermore, in this specification, the term "node" can be replaced with other terms such as "terminal," "wiring," "electrode," "conductive layer," "conductor," or "impurity region," depending on the circuit configuration or device structure. Also, terms such as "terminal" or "wiring" can be replaced with "node."

[0040] Furthermore, in this specification, the ordinal numbers "first," "second," or "third" are used to avoid confusion of constituent elements. Therefore, they do not limit the number of constituent elements, nor do they limit the order of the constituent elements. For example, a constituent element referred to as "first" in one embodiment of this specification may be referred to as "second" in another embodiment or claim. Also, for example, a constituent element referred to as "first" in one embodiment of this specification may be omitted in another embodiment or claim.

[0041] Furthermore, in this specification, phrases indicating arrangement, such as "above," "below," "upward," or "downward," are sometimes used for convenience to explain the positional relationships between components with reference to the drawings. Also, the positional relationships between components change as appropriate depending on the direction in which each component is depicted. Therefore, the phrases indicating arrangement described in this specification are not limited to those described and can be appropriately rephrased depending on the situation. For example, the expression "insulator located on the upper surface of the conductor" can be rephrased as "insulator located on the lower surface of the conductor" by rotating the orientation of the drawing shown by 180 degrees.

[0042] Furthermore, the terms "above" or "below" do not limit the positional relationship of the components to being directly above or below each other and in direct contact. For example, the expression "electrode B on insulating layer A" does not require that electrode B be formed in direct contact with insulating layer A, and does not exclude cases where other components are included between insulating layer A and electrode B.

[0043] Furthermore, in this specification, terms such as "overlapping" do not limit the state of the components, such as the stacking order. For example, the expression "electrode B overlapping insulating layer A" is not limited to a state in which electrode B is formed on top of insulating layer A. The expression "electrode B overlapping insulating layer A" does not exclude, for example, a state in which electrode B is formed below insulating layer A, or a state in which electrode B is formed to the right (or left) of insulating layer A.

[0044] Furthermore, in this specification, the terms "adjacent" or "proximity" are not limited to direct contact between components. For example, the expression "electrode B adjacent to insulating layer A" does not require that insulating layer A and electrode B be formed in direct contact, and does not exclude cases where other components are included between insulating layer A and electrode B.

[0045] Furthermore, in this specification, terms such as "film" or "layer" may be interchangeable depending on the context. For example, the term "conductive layer" may be changed to the term "conductive film." For example, the term "insulating film" may be changed to the term "insulating layer." Also, terms such as "film" or "layer" may be replaced with other terms depending on the context, without using those terms. For example, the term "conductive layer" or "conductive film" may be changed to the term "conductor." Also, the term "conductor" may be changed to the term "conductive layer" or "conductive film." For example, the term "insulating layer" or "insulating film" may be changed to the term "insulator." Also, the term "insulator" may be changed to the term "insulating layer" or "insulating film."

[0046] Furthermore, in this specification, terms such as "electrode," "wiring," or "terminal" do not functionally limit these components. For example, "electrode" may be used as part of "wiring," and vice versa. Moreover, the terms "electrode" or "wiring" also include cases where multiple "electrodes" or "wiring" are formed as a single unit. Similarly, for example, "terminal" may be used as part of "wiring" or "electrode," and vice versa. Furthermore, the term "terminal" also includes cases where multiple "electrodes," "wiring," or "terminals" are formed as a single unit. Therefore, for example, "electrode" can be part of "wiring" or "terminal." Also, for example, "terminal" can be part of "wiring" or "electrode." In addition, terms such as "electrode," "wiring," or "terminal" may be replaced with terms such as "region."

[0047] Furthermore, in this specification, terms such as "wiring," "signal line," or "power line" may be interchangeable depending on the context. For example, the term "wiring" may be changed to the term "signal line." Similarly, the term "wiring" may be changed to the term "power line." The same applies in reverse; for example, terms such as "signal line" or "power line" may be changed to the term "wiring." Similarly, terms such as "power line" may be changed to the term "signal line." Similarly, the same applies in reverse; for example, terms such as "signal line" may be changed to the term "power line." Furthermore, the term "potential" applied to wiring may be changed to the term "signal," depending on the context. Similarly, the same applies in reverse; for example, terms such as "signal" may be changed to the term "potential."

[0048] Furthermore, in this specification, "switch" refers to a device having multiple terminals and a function to switch (select) between continuity and non-continuity between those terminals. For example, if a switch has two terminals and there is continuity between both terminals, the switch is said to be in a "conductive state" or "on state." If there is no continuity between both terminals, the switch is said to be in a "non-conductive state" or "off state." Note that the act of switching the switch to either a continuative or non-conductive state, or maintaining either a continuative or non-conductive state, may be referred to as "controlling the continuity state."

[0049] In short, a switch is a device that controls whether or not an electric current flows. Alternatively, a switch is a device that selects and switches the path through which an electric current flows. Examples of switches include electrical switches and mechanical switches. In other words, a switch can be anything that can control an electric current, and is not limited to any particular type.

[0050] Examples of switches include transistors (e.g., bipolar transistors or MOS transistors), diodes (e.g., PN diodes, PIN diodes, Schottky diodes, MIM (Metal Insulator Metal) diodes, MIS (Metal Insulator Semiconductor) diodes, or diode-connected transistors), or logic circuits combining these. When a transistor is used as a switch, the "conducting state" or "on state" of the transistor refers to a state in which the source and drain electrodes of the transistor can be considered to be electrically short-circuited. Conversely, the "non-conducting state" or "off state" of the transistor refers to a state in which the source and drain electrodes of the transistor can be considered to be electrically disconnected. When a transistor is used simply as a switch, the polarity (conductivity type) of the transistor is not particularly limited.

[0051] One example of a mechanical switch is a switch using MEMS (Micro-Electro-Mechanical Systems) technology. This switch has mechanically movable electrodes, and the movement of these electrodes selects between a conductive state and a non-conductive state.

[0052] In this specification, "parallel" means a state in which two lines are positioned at an angle of -10° or more and 10° or less. Therefore, the case of -5° or more and 5° or less is also included. Furthermore, "approximately parallel" or "roughly parallel" means a state in which two lines are positioned at an angle of -30° or more and 30° or less. Furthermore, "perpendicular" means a state in which two lines are positioned at an angle of 80° or more and 100° or less. Therefore, the case of 85° or more and 95° or less is also included. Furthermore, "approximately perpendicular" or "roughly perpendicular" means a state in which two lines are positioned at an angle of 60° or more and 120° or less.

[0053] In this specification, when count values ​​and measured values ​​are referred to as, for example, "identical," "same," "equal," or "uniform" (including synonyms), these shall include an error margin of plus or minus 20%, unless otherwise explicitly stated.

[0054] Embodiments described herein will be explained with reference to the drawings. However, embodiments can be implemented in many different ways. Therefore, it will be readily apparent to those skilled in the art that their form and details can be modified in various ways without departing from the spirit and scope. Accordingly, the present invention is not to be construed as being limited to the contents of the embodiments. In addition, in drawings illustrating embodiments, the same reference numerals may be used in common across different drawings for parts that are the same or have similar functions in the configuration of the invention, thereby omitting repeated explanations. Also, in drawings, the same hatching pattern may be used when referring to similar functions, and reference numerals may not be assigned. Furthermore, in order to facilitate understanding, some components may be omitted in drawings, for example, in perspective views or top views.

[0055] Furthermore, in the drawings and other illustrations relating to this specification, the size, layer thickness, or area may be exaggerated for clarity. Therefore, the drawings are not necessarily limited to, for example, their size or aspect ratio. Moreover, the drawings are schematic representations of ideal examples and are not limited to, for example, the shapes or values ​​shown in the drawings. For example, they may include variations in signals, voltages, or currents due to noise, or variations in signals, voltages, or currents due to timing differences.

[0056] Furthermore, in drawings and other illustrations relating to this specification, arrows indicating the X, Y, and Z directions may be included. In this specification, the "X direction" is the direction along the X-axis, and unless explicitly stated, forward and reverse directions may not be distinguished. The same applies to the "Y direction" and "Z direction." Also, the X, Y, and Z directions are directions that intersect each other. More specifically, the X, Y, and Z directions are directions that are orthogonal to each other. In this specification, one of the X, Y, or Z directions may be referred to as the "first direction" or "first direction." Another may be referred to as the "second direction" or "second direction." The remaining one may be referred to as the "third direction" or "third direction."

[0057] In this specification, when the same symbol is used for multiple elements, and especially when it is necessary to distinguish them, an identifying code such as "A", "b", "_1", "[n]", or "[m,n]" may be added to the symbol.

[0058] (Embodiment 1) A semiconductor device 100A according to one aspect of the present invention will now be described. The semiconductor device 100A according to one aspect of the present invention can be used, for example, as a pixel in a display device.

[0059] <Example Configuration> Figure 1 shows an example of the circuit configuration of semiconductor device 100A. The semiconductor device 100A includes a pixel circuit 51A and a light-emitting element 61. The pixel circuit 51A includes transistors M1 to M7 and capacitors C1 to C3. In this embodiment, transistors M1 to M7 are enhancement-type (normally-off type) n-channel field-effect transistors unless otherwise specified. Therefore, the threshold voltage (also called "Vth") of each of transistors M1 to M7 is greater than 0V. Note that the threshold voltages of each of transistors M1 to M7 may be different. For example, the threshold voltage of transistor M2 may be called Vth2. Also, the threshold voltage of transistor M5 may be called Vth5. Also, the threshold voltage of transistor M7 may be called Vth7.

[0060] The gate of transistor M1 is electrically connected to wiring GLa. Either the source or drain of transistor M1 is electrically connected to wiring DL. The other source or drain of transistor M1 is electrically connected to the gate of transistor M2. Transistor M1 has the function of making the connection between the gate of transistor M2 and wiring DL conductive or non-conductive.

[0061] The gate of transistor M2 is electrically connected to one terminal of capacitor C1. One of the source or drain of transistor M2 is electrically connected to wiring 101. The other of the source or drain of transistor M2 is electrically connected to the other terminal of capacitor C1. Transistor M2 also has a back gate. The back gate of transistor M2 is electrically connected to one terminal of capacitor C2. The other terminal of capacitor C2 is electrically connected to the other of the source or drain of transistor M2.

[0062] The gate of transistor M3 is electrically connected to wiring GLB. One of the sources or drains of transistor M3 is electrically connected to one terminal of capacitor C1. The other of the sources or drains of transistor M3 is electrically connected to the other terminal of capacitor C1. Transistor M3 has the function of making the connection between the gate of transistor M2 and the other of the sources or drains of transistor M2 conductive or non-conductive.

[0063] The gate of transistor M4 is electrically connected to wiring GLB. One of the source or drain of transistor M4 is electrically connected to wiring 102. The other of the source or drain of transistor M4 is electrically connected to one terminal of capacitor C2. Transistor M4 has the function of making the connection between wiring 102 and one terminal of capacitor C2 conductive or non-conductive.

[0064] The gate of transistor M5 is electrically connected to one terminal of capacitor C3. One source or drain of transistor M5 is electrically connected to the other source or drain of transistor M2. The other source or drain of transistor M5 is electrically connected to the other terminal of capacitor C3 and to one terminal of light-emitting element 61 (e.g., the anode terminal). The other terminal of light-emitting element 61 (e.g., the cathode terminal) is electrically connected to wiring 104.

[0065] The gate of transistor M6 is electrically connected to wiring GLd. One of the sources or drains of transistor M6 is electrically connected to the other source or drain of transistor M2. The other source or drain of transistor M6 is electrically connected to wiring 103. Transistor M6 has the function of making the connection between the other source or drain of transistor M2 and wiring 103 conductive or non-conductive.

[0066] The gate of transistor M7 is electrically connected to the wiring GLd. Either the source or drain of transistor M7 is electrically connected to the wiring GLc. The other source or drain of transistor M7 is electrically connected to the gate of transistor M5. Transistor M7 has the function of making the connection between the gate of transistor M5 and the wiring GLc conductive or non-conductive.

[0067] Furthermore, the region in which the other terminal of capacitor C1, the other terminal of capacitor C2, the other source or drain of transistor M2, the other source or drain of transistor M3, one source or drain of transistor M5, and one source or drain of transistor M6 are each electrically connected to one another is also called node ND1.

[0068] Furthermore, the region where one terminal of capacitor C2, the back gate of transistor M2, and the other source or drain of transistor M4 are electrically connected to each other is also called node ND2.

[0069] Furthermore, the region in which the other source or drain of transistor M1, the other source or drain of transistor M3, one terminal of capacitor C1, and the gate of transistor M2 are electrically connected to each other is also called node ND3.

[0070] Furthermore, the region where the gate of transistor M5, one terminal of capacitor C3, and the other source or drain of transistor M7 are electrically connected to each other is also called node ND4.

[0071] Capacitor C1 has the function of maintaining the potential difference between the source or drain of transistor M2 and the gate of transistor M2 when node ND3 is floating. Capacitor C2 has the function of maintaining the potential difference between the source or drain of transistor M2 and the back gate of transistor M2 when node ND2 is floating. Capacitor C3 has the function of maintaining the potential difference between the source or drain of transistor M5 and the gate of transistor M5 when node ND4 is floating.

[0072] A transistor containing various semiconductors can be used in the pixel circuit 51A according to one aspect of the present invention. For example, a transistor containing a single-crystal semiconductor, a polycrystalline semiconductor, a microcrystalline semiconductor, or an amorphous semiconductor can be used in the channel formation region. The semiconductor contained in the transistor is not limited to a single-element semiconductor whose main component is a single element (e.g., silicon (Si) or germanium (Ge)). As the semiconductor contained in the transistor, for example, a compound semiconductor (e.g., silicon germanium (SiGe) or gallium arsenide (GaAs)) or an oxide semiconductor can be used.

[0073] Furthermore, while this embodiment and others show an example of configuring the semiconductor device 100A using n-channel transistors, the present invention is not limited thereto. Some or all of the transistors constituting the semiconductor device 100A may be p-channel transistors.

[0074] Furthermore, transistors of various structures can be used in the pixel circuit 51A according to one aspect of the present invention. For example, transistors of various configurations can be used, such as planar type, fin type, tri-gate type, top-gate type, bottom-gate type, or dual-gate type (a structure in which gates are arranged above and below the channel). In addition, as a transistor according to one aspect of the present invention, for example, a MOS type transistor, a junction type transistor, or a bipolar transistor can be used.

[0075] For example, an OS transistor (a transistor containing an oxide semiconductor in the semiconductor layer where the channel is formed) may be used as the transistor constituting the pixel circuit 51A. Since oxide semiconductors have a band gap of 2 eV or more, their off-current is extremely low.

[0076] At room temperature, the off-current value of an OS transistor per 1 μm channel width is 1 aA (1 × 10⁻¹⁶). -18 A) Below, 1zA(1×10 -21 A) Less than or equal to 1yA(1×10 -24 A) It can be less than or equal to the above. Note that the off-current value of a Si transistor (a transistor in which the semiconductor layer on which the channel is formed contains silicon) per 1 μm of channel width at room temperature is 1 fA (1 × 10⁻¹⁶). -15 A) More than 1pA (1×10 -12 A) The answer is as follows. Therefore, it can be said that the off-current of an OS transistor is about 10 orders of magnitude lower than that of a Si transistor.

[0077] By using OS transistors in the pixel circuit 51A, the charge written to each node of the pixel circuit 51A can be retained for a long period of time. For example, when displaying a still image that does not require rewriting for each frame, the pixel circuit 51A can continue displaying the image even if the operation of the peripheral drive circuit is stopped. This method of stopping the operation of the peripheral drive circuit while displaying a still image is also called "idling stop drive". By performing idling stop drive, the power consumption of the display device can be reduced.

[0078] Furthermore, OS transistors exhibit almost no increase in off-current even in high-temperature environments. Specifically, OS transistors show almost no increase in off-current even at ambient temperatures between room temperature and 200°C. In addition, OS transistors maintain a low on-current even in high-temperature environments. Semiconductor devices containing OS transistors operate stably and with high reliability even in high-temperature environments.

[0079] Furthermore, OS transistors have high dielectric strength between the source and drain. By using OS transistors in the transistors that make up the pixel circuit 51A, operation remains stable even when there is a large potential difference between the potential supplied to wiring 101 (also called the anode potential) and the potential supplied to wiring 104 (also called the cathode potential). OS transistors enable the realization of highly reliable semiconductor devices. In particular, it is preferable to use OS transistors for one or both of transistors M2 and M5.

[0080] The semiconductor layer of the OS transistor preferably contains at least one of indium and zinc. Furthermore, the semiconductor layer of the OS transistor preferably contains, for example, indium, M (where M is one or more selected from gallium, aluminum, silicon, boron, yttrium, tin, copper, vanadium, beryllium, titanium, iron, nickel, germanium, zirconium, molybdenum, lanthanum, cerium, neodymium, hafnium, tantalum, tungsten, and magnesium), and zinc. In particular, M is preferably one or more selected from aluminum, gallium, yttrium, and tin.

[0081] In particular, it is preferable to use an oxide containing indium (In), gallium (Ga), and zinc (Zn) (also referred to as "IGZO") as the semiconductor layer. Alternatively, an oxide containing indium (In), aluminum (Al), and zinc (Zn) (also referred to as "IAZO") may be used as the semiconductor layer. Alternatively, an oxide containing indium (In), aluminum (Al), gallium (Ga), and zinc (Zn) (also referred to as "IAGZO") may be used as the semiconductor layer.

[0082] When the semiconductor layer is an In-M-Zn oxide, it is preferable that the atomic ratio of In in the In-M-Zn oxide is greater than or equal to the atomic ratio of M. Examples of such atomic ratios of metal elements in an In-M-Zn oxide include: In:M:Zn=1:1:1 or close to it, In:M:Zn=1:1:1.2 or close to it, In:M:Zn=1:3:2 or close to it, In:M:Zn=1:3:4 or close to it, In:M:Zn=2:1:3 or close to it, In:M:Zn=3:1:2 or close to it, and In:M:Zn=4:2:3 Examples include compositions near the desired atomic ratio, such as In:M:Zn=4:2:4.1 or near that ratio, In:M:Zn=5:1:3 or near that ratio, In:M:Zn=5:1:6 or near that ratio, In:M:Zn=5:1:7 or near that ratio, In:M:Zn=5:1:8 or near that ratio, In:M:Zn=6:1:6 or near that ratio, or In:M:Zn=5:2:5 or near that ratio. Note that "nearby composition" includes a range of plus or minus 30% of the desired atomic ratio.

[0083] For example, when describing a composition with an atomic ratio of In:Ga:Zn = 4:2:3 or a similar ratio, it includes cases where, when the atomic ratio of In is 4, the atomic ratio of Ga is between 1 and 3, and the atomic ratio of Zn is between 2 and 4. Also, when describing a composition with an atomic ratio of In:Ga:Zn = 5:1:6 or a similar ratio, it includes cases where, when the atomic ratio of In is 5, the atomic ratio of Ga is greater than 0.1 and 2 or less, and the atomic ratio of Zn is between 5 and 7. Furthermore, when describing a composition with an atomic ratio of In:Ga:Zn = 1:1:1 or a similar ratio, it includes cases where, when the atomic ratio of In is 1, the atomic ratio of Ga is greater than 0.1 and 2 or less, and the atomic ratio of Zn is greater than 0.1 and 2 or less.

[0084] Furthermore, the pixel circuit 51A may be composed of multiple types of transistors using different semiconductor materials. For example, the pixel circuit 51A may be composed of transistors having low-temperature polysilicon (LTPS) in the semiconductor layer (hereinafter also referred to as LTPS transistors) and OS transistors. LTPS transistors have high field-effect mobility and good frequency characteristics. A configuration combining LTPS transistors and OS transistors is sometimes referred to as LTPO.

[0085] If the pixel circuit 51A is composed of multiple types of transistors using different semiconductor materials, the transistors may be placed on different layers for each type of transistor. For example, if the pixel circuit 51A is composed of Si transistors and OS transistors, the layer containing the Si transistors and the layer containing the OS transistors may be placed on top of each other. This configuration reduces the area occupied by the pixel circuit 51A.

[0086] Furthermore, transistor M2 has the function of controlling the amount of current flowing to the light-emitting element 61. In other words, transistor M2 has the function of controlling the amount of light emitted by the light-emitting element 61. Therefore, in this specification, transistor M2 may be referred to as the "driving transistor".

[0087] Furthermore, transistor M5 has the function of making the connection between transistor M2 and the light-emitting element 61 either conductive (also called on) or non-conductive (also called off). When transistor M5 is in the off state, no current flows to the light-emitting element 61, so the light-emitting element 61 stops emitting light (extinguishing). When transistor M5 is in the on state, current flows to the light-emitting element 61 through transistor M5, causing the light-emitting element 61 to emit light. Therefore, in this specification, transistor M5 may be referred to as the "light-emitting transistor". When emitting light, transistor M5 must be reliably in the on state, regardless of the values ​​of its source potential and drain potential, in order to supply a current of the amount determined by the driving transistor to the light-emitting element 61.

[0088] Of the transistors constituting the pixel circuit 51A, transistors M1, M3, M4, M6, and M7 function as switches. Therefore, the semiconductor device 100A can be shown as in Figure 2.

[0089] Furthermore, transistor M5 also functions as a switch. Therefore, the semiconductor device 100A can also be shown as in Figure 3. Transistors M1 and M3 to M7 can be replaced with elements that can realize the function of a switch.

[0090] All or some of the transistors constituting the pixel circuit 51A may be transistors having back gates. By providing a back gate to a transistor, the electric field generated outside the transistor is less likely to act on the channel formation region. As a result, the operation of the semiconductor device using the transistor becomes more stable and reliable. In addition, by applying the same potential to the back gate of the transistor as to the gate, the on-resistance of the transistor is reduced. Furthermore, by controlling the potential of the back gate of the transistor independently of the gate potential, the threshold voltage of the transistor can be changed.

[0091] Figure 4 shows an example of the circuit configuration of semiconductor device 100A, in which not only transistor M2, but also transistors M1 and M3 through M7 are composed of transistors with back gates. Figure 4 shows an example in which the gate and back gate are electrically connected in each of transistors M1 and M3 through M7. However, it is not necessary for all transistors constituting the semiconductor device to be provided with back gates.

[0092] Furthermore, in transistor M1 and transistors M3 through M7, the gate and back gate may not be electrically connected, and an arbitrary potential may be supplied to the back gate. Note that the potential supplied to the back gate is not limited to a fixed potential. The potential supplied to the back gate of the transistors constituting the semiconductor device may be different for each transistor or may be the same for each transistor.

[0093] Figure 5 is an example of a planar layout diagram of the semiconductor device 100A shown in Figure 4.

[0094] The semiconductor layer 112 of transistor M1 is provided on the conductive layer 111. The conductive layer 111 and the semiconductor layer 112 have overlapping regions. A portion of the conductive layer 111 functions as the back gate of transistor M1. The conductor 113 functions as the gate of transistor M1. The conductor 113 is also electrically connected to the conductive layer 111 and the wiring GLa at the contact hole 114.

[0095] One of the sources or drains of transistor M1 is electrically connected to wiring DL via conductive layer 115. The other of the sources or drains of transistor M1 is electrically connected to conductive layer 116.

[0096] The semiconductor layer 118 of transistor M2 is provided on the conductive layer 117. The conductive layer 117 and the semiconductor layer 118 have overlapping regions. A portion of the conductive layer 117 functions as the back gate of transistor M2. The conductive layer 119 functions as the gate of transistor M2. The conductive layer 119 is also electrically connected to the conductive layer 116.

[0097] One of the sources or drains of transistor M2 is electrically connected to wiring 101 via conductive layer 121. The other of the sources or drains of transistor M2 is electrically connected to conductive layer 122. Conductive layer 122 is electrically connected to conductive layer 123. The region where conductive layer 116 and conductive layer 123 overlap functions as capacitance C1.

[0098] The semiconductor layer 125 of transistor M3 is provided on the conductive layer 124. The conductive layer 124 and the semiconductor layer 125 have overlapping regions. A portion of the conductive layer 124 functions as the back gate of transistor M3. The conductor 126 functions as the gate of transistor M3. The conductor 126 is also electrically connected to the conductive layer 124 and the wiring GLb at the contact hole 127.

[0099] One of the sources or drains of transistor M3 is electrically connected to the conductive layer 116. The other of the sources or drains of transistor M3 is electrically connected to the conductive layer 122.

[0100] The semiconductor layer 128 of transistor M4 is provided on the conductive layer 124. The conductive layer 124 and the semiconductor layer 128 have overlapping regions. A portion of the conductive layer 124 functions as the back gate of transistor M4. The conductor 126 functions as the gate of transistor M4.

[0101] One of the sources or drains of transistor M4 is electrically connected to wiring 102 via conductive layer 129. The other of the sources or drains of transistor M4 is electrically connected to conductive layer 131. Conductive layer 131 is electrically connected to conductive layer 117. The region where conductive layer 131 and conductive layer 123 overlap functions as capacitance C2.

[0102] The semiconductor layer 133 of transistor M5 is provided on the conductive layer 132. The conductive layer 132 and the semiconductor layer 133 have overlapping regions. A portion of the conductive layer 132 functions as the back gate of transistor M5. The conductor 134 functions as the gate of transistor M5. In addition, the conductor 134 is electrically connected to the conductive layer 132 and the conductive layer 136 at the contact hole 135.

[0103] One of the sources or drains of transistor M5 is electrically connected to conductive layer 122. The other source or drain of transistor M5 is electrically connected to conductive layer 137. Conductive layer 137 is electrically connected to conductive layer 138. The region where conductive layers 136 and 138 overlap functions as capacitance C3. Conductive layer 137 is also electrically connected to the light-emitting element 61.

[0104] The semiconductor layer 141 of transistor M6 is provided on the conductive layer 139. The conductive layer 139 and the semiconductor layer 141 have overlapping regions. A portion of the conductive layer 139 functions as the back gate of transistor M6. The conductor 142 functions as the gate of transistor M6. The conductor 142 is also electrically connected to the conductive layer 139 and the wiring GLd at the contact hole 143.

[0105] One of the sources or drains of transistor M6 is electrically connected to the conductive layer 122. The other of the sources or drains of transistor M6 is electrically connected to the wiring 103 via the conductive layer 144.

[0106] The semiconductor layer 145 of transistor M7 is provided on the conductive layer 139. The conductive layer 139 and the semiconductor layer 145 have overlapping regions. A portion of the conductive layer 139 functions as the back gate of transistor M7. The conductor 142 functions as the gate of transistor M7.

[0107] One of the sources or drains of transistor M7 is electrically connected to the wiring GLc via the conductive layer 146. The other of the sources or drains of transistor M7 is electrically connected to the conductive layer 136.

[0108] Conductive layer 122 functions as node ND1. Conductive layer 131 functions as node ND2. Conductive layer 116 functions as node ND3. Conductive layer 136 functions as node ND4.

[0109] The transistors constituting the pixel circuit 51A may be single-gate transistors with one gate between the source and drain, or double-gate transistors. Figure 6A is an example of a circuit symbol for a double-gate transistor 180A.

[0110] Transistor 180A has a configuration in which transistors Tr1 and Tr2 are connected in series. In Figure 6A, one source or drain of transistor Tr1 is electrically connected to terminal S, the other source or drain of transistor Tr1 is electrically connected to one source or drain of transistor Tr2, and the other source or drain of transistor Tr2 is electrically connected to terminal D. In addition, the gates of transistor Tr1 and transistor Tr2 are electrically connected to each other and are also electrically connected to terminal G.

[0111] The transistor 180A shown in Figure 6A has the function of making the connection between terminals S and D conductive or non-conductive by changing the potential of terminal G. Therefore, the double-gate transistor 180A contains transistors Tr1 and Tr2 and functions as a single transistor. In other words, in Figure 6A, one of the source or drain of transistor 180A is electrically connected to terminal S, the other source or drain is electrically connected to terminal D, and the gate is electrically connected to terminal G.

[0112] Furthermore, the transistors constituting the pixel circuit 51A may be triple-gate transistors. Figure 6B shows an example of a circuit symbol for a triple-gate transistor 180B.

[0113] Transistor 180B has a configuration in which transistors Tr1, Tr2, and Tr3 are connected in series. In Figure 6B, one source or drain of transistor Tr1 is electrically connected to terminal S, the other source or drain of transistor Tr1 is electrically connected to one source or drain of transistor Tr2, the other source or drain of transistor Tr2 is electrically connected to one source or drain of transistor Tr3, and the other source or drain of transistor Tr3 is electrically connected to terminal D. In addition, the gates of transistors Tr1, Tr2, and Tr3 are each electrically connected to each other and are also electrically connected to terminal G.

[0114] The transistor 180B shown in Figure 6B has the function of making the connection between terminals S and D conductive or non-conductive by changing the potential of terminal G. Therefore, the triple-gate transistor 180B contains transistors Tr1, Tr2, and Tr3 and functions as a single transistor. In other words, in Figure 6B, one of the source or drain of transistor 180B is electrically connected to terminal S, the other source or drain is electrically connected to terminal D, and the gate is electrically connected to terminal G.

[0115] Furthermore, the transistors constituting the pixel circuit 51A may be configured with four or more transistors connected in series. The transistor 180C shown in Figure 6C has a configuration in which six transistors (transistors Tr1 to Tr6) are connected in series. In addition, the gates of each of the six transistors are electrically connected to each other and are also electrically connected to terminal G.

[0116] The transistor 180C shown in Figure 6C has the function of making the connection between terminals S and D conductive or non-conductive by changing the potential of terminal G. Therefore, transistor 180C contains transistors Tr1 to Tr6 and functions as a single transistor. In other words, in Figure 6C, one of the source or drain of transistor 180C is electrically connected to terminal S, the other source or drain is electrically connected to terminal D, and the gate is electrically connected to terminal G.

[0117] Transistors that have multiple gates, each of which is electrically connected to the others, such as transistors 180A, 180B, and 180C, are sometimes called "multi-gate transistors."

[0118] For example, a longer channel length of a transistor may be desirable to improve its electrical characteristics in the saturation region. Multi-gate transistors may be used to realize transistors with long channel lengths.

[0119] As the light-emitting element 61, various display elements such as EL elements (EL elements containing organic and inorganic materials, organic EL elements, or inorganic EL elements), LEDs (e.g., white LEDs, red LEDs, green LEDs, or blue LEDs), microLEDs (e.g., LEDs with sides less than 0.1 mm), QLEDs (Quantum-dot Light Emitting Diodes), or electron-emitting elements may be used.

[0120] <Example of operation> Next, an example of the operation of semiconductor device 100A will be explained using drawings. Figure 7 is a timing chart for illustrating an example of the operation of semiconductor device 100A. Figures 8 to 13 are circuit diagrams for illustrating an example of the operation of semiconductor device 100A.

[0121] The video signal Vdata is supplied to wiring DL. Therefore, wiring DL is sometimes referred to as a "signal line". Potential Va is supplied to wiring 101, potential V1 to wiring 102, potential V0 to wiring 103, and potential Vc to wiring 104. In addition, either potential H or potential L is supplied to wiring GLa, wiring GLB, wiring GLC, and wiring GLD, respectively. Potential H is preferably a higher potential than potential L. In this specification, "potential H" is the potential supplied to the gate of an n-channel transistor that turns the transistor ON. "Potential L" is the potential supplied to the gate of an n-channel transistor that turns the transistor OFF.

[0122] Potential Va is the anode potential, and potential Vc is the cathode potential. Furthermore, it is preferable that potential V1 is higher than potential V0. For example, potential V1 may be the potential supplied to the gate of a transistor that turns the transistor ON. Also, for example, potential V0 may be the potential supplied to the gate of a transistor that turns the transistor OFF. Potential V0 is, for example, 0V or potential L. Furthermore, it is preferable that potential H is higher than potential V1. In this embodiment, for example, potential V0 is assumed to be 0V, and potential V1 is assumed to be 5V. Also, potential Va is assumed to be 15V, potential Vc is assumed to be 0V, and potential H is assumed to be 6V.

[0123] The semiconductor device 100A has a function to control the magnitude of the current Ie (see Figure 12) flowing through the light-emitting element 61 in accordance with the video signal Vdata supplied from the wiring DL. The luminescence brightness of the light-emitting element 61 is controlled by the magnitude of the current Ie.

[0124] In drawings, symbols indicating potential, such as "H," "L," "V0," or "V1" (also called "potential symbols"), may be written adjacent to terminals or wiring. Furthermore, to make potential changes easier to understand, potential symbols added to terminals or wiring where a potential change has occurred may be enclosed in a box. Additionally, an "×" symbol may be superimposed on an off-state transistor.

[0125] The current Ie flowing through the light-emitting element 61 is mainly determined by the video signal Vdata and the Vth2 of transistor M2. Therefore, even if the same video signal Vdata is supplied to multiple pixel circuits, if the Vth2 of transistor M2 in each pixel circuit is different, the current Ie will differ for each pixel. Thus, variations in the Vth2 of transistor M2 contribute to a decrease in display quality.

[0126] Therefore, by acquiring the Vth2 of transistor M2 for each pixel, the variation in current Ie is reduced. Note that the operation of acquiring the Vth2 of transistor M2 is sometimes referred to as "Vth value correction operation."

[0127] In this specification and other documents, a series of operations that change the conduction or non-conduction state of a transistor, supply charge to a node electrically connected to the transistor, and change the potential of the node may be referred to as "processing."

[0128] [Vth correction operation] First, during period T11, a reset operation is performed. Specifically, potential H is supplied to wiring GLb and wiring GLd, and potential L is supplied to wiring GLa and wiring GLc (see Figure 8).

[0129] As a result, transistors M3, M4, M6, and M7 turn on, while transistor M1 turns off.

[0130] Therefore, potential V0 is supplied to node ND1 via transistor M6. Furthermore, potential V0 is supplied to node ND3 via transistors M6 and M3. Also, potential V1 is supplied to node ND2 via transistor M4. And potential L is supplied to node ND4 via transistor M7. Consequently, transistor M5 is in the off state.

[0131] Next, during period T12, a potential L is supplied to the wiring GLd (see Figure 9). As a result, transistors M6 and M7 turn off. Therefore, node ND4 becomes floating, and the charge supplied to node ND4 is retained. Thus, the off state of transistor M5 is maintained.

[0132] Since the potential of node ND2 is potential V1, transistor M2 is in the ON state. As a result, charge is supplied to node ND1 from wiring 101 via transistor M2. Therefore, the potential of node ND1 rises. Also, since transistor M3 is in the ON state, the potential of node ND3 rises as well. Specifically, the potentials of nodes ND1 and ND3 rise to the value obtained by subtracting the Vth2 of transistor M2 from the potential V1.

[0133] Here, since the potential of node ND2 is fixed at potential V1, as the potentials of nodes ND1 and ND3 rise, the potential difference between the back gate and the source of transistor M2 decreases. When the potential of node ND1 rises to near potential V1-Vth2, the current flowing from wiring 101 through transistor M2 to node ND1 decreases. Therefore, the rate at which the potential of node ND1 rises slows down. Thus, it is desirable that the period T12 be sufficiently long as it is the time required for the potential of node ND1 to rise to potential V1-Vth2. Specifically, the period T12 is preferably 1 μs or longer, and more preferably 10 μs or longer.

[0134] Next, during period T13, a potential L is supplied to wiring GLb (see Figure 10). As a result, transistors M3 and M4 turn off. Therefore, nodes ND2 and ND3 become floating. Thus, the charge supplied to each node is retained. Since transistor M7 is off, the potential of wiring GLc does not affect its operation. That is, the charge supplied to node ND4 is retained. Therefore, the off state of transistor M5 is maintained. Here, we have shown an example in which a potential H is supplied to wiring GLc during period T13, but a potential H may also be supplied to wiring GLc during period T14, which will be explained next.

[0135] [Data writing operation] During period T14, a potential H is supplied to wirings GLa and GLd (see Figure 11). As a result, transistor M1 turns on. Therefore, the video signal Vdata is supplied to node ND3. Also, transistor M6 turns on. Therefore, a potential V0 is supplied to node ND1.

[0136] Nodes ND1 and ND2 are capacitively coupled via capacitor C2. Therefore, when the potential of node ND1 changes from V1-Vth2 to V0, the potential of node ND2 also changes accordingly. In this embodiment, since potential V0 is 0V, the potential of node ND2 is expressed as potential V1-(potential V1-Vth2). That is, the potential of node ND2 becomes Vth2.

[0137] Also, transistor M7 turns ON. As a result, charge is supplied from wiring GLc to node ND4. Then, the potential of node ND4 rises to the value obtained by subtracting the Vth7 of transistor M7 from the potential H. In this embodiment, the potential H is 6V. If the Vth5 of transistor M5 and the Vth7 of transistor M7 are both 1V, then the potential of node ND4 (potential H - Vth7) becomes 5V. Then, transistor M5 turns ON. Therefore, the potential of the anode terminal of the light-emitting element 61 becomes potential V0.

[0138] [Light emission operation] During period T15, a potential L is supplied to wirings GLa and GLd (see Figure 12). As a result, transistors M1 and M6 turn off. Therefore, current flows from wiring 101 to wiring 104. That is, current Ie flows to the light-emitting element 61. Thus, the light-emitting element 61 emits light with brightness corresponding to the current Ie. In addition, the current flowing from wiring 101 to wiring 104 increases the potential of node ND1 and the anode terminal of the light-emitting element 61.

[0139] Furthermore, node ND3 is in a floating state, and nodes ND1 and ND3 are capacitively coupled via capacitor C1. Therefore, when the potential of node ND1 changes from potential V0 to potential Va1, the potential of node ND3 also changes accordingly. In this embodiment, the potential of node ND3 becomes the video signal Vdata + potential Va1. In other words, even if the source potential of transistor M2 changes, the potential difference (voltage) between the gate and source of transistor M2 remains the same as the video signal Vdata.

[0140] Similarly, node ND2 is floating, and nodes ND1 and ND3 are capacitively coupled via capacitor C1. Therefore, in response to the potential change at node ND1, the potential at node ND2 becomes Vth2 + potential Va1. In other words, the potential difference between the back gate and the source of transistor M2 remains at Vth2.

[0141] Furthermore, when transistor M7 is turned off, node ND4 becomes floating. The anode terminal of the light-emitting element 61 and node ND4 are capacitively coupled via capacitor C3. Therefore, when the potential of the anode terminal of the light-emitting element 61 changes from potential V0 to potential Va2, the potential of node ND4 also changes accordingly. In this embodiment, since potential V0 is 0V, the potential of node ND4 becomes potential H-Vth7 + potential Va2. In other words, even if the potential of the anode terminal of the light-emitting element 61 changes, the potential difference (voltage) between the gate and source of transistor M5 remains at potential H-Vth7.

[0142] For example, if the gate of transistor M5 is at a fixed potential, increasing the source potential of transistor M5 will decrease the potential difference between the gate and source of transistor M5. When the potential difference between the gate and source of transistor M5 falls below the threshold voltage of transistor M5, transistor M5 will turn off. Therefore, when increasing the anode potential, the fixed potential supplied to the gate of transistor M5 must also be increased. Thus, an additional power supply or power supply circuit is required.

[0143] In a semiconductor device 100A according to one aspect of the present invention, a bootstrap circuit is configured by providing a capacitor C3 between the gate and source of transistor M5. This allows the ON state of transistor M5 to be maintained even when the anode potential is increased, without the need to add a power supply circuit. As a result, a stable current Ie is supplied to the light-emitting element 61. Capacitor C3 is sometimes referred to as a "bootstrap capacitor." Capacitors C1 and C2 also function as bootstrap capacitors.

[0144] A semiconductor device 100A according to one aspect of the present invention is suitably used not only for single-structure light-emitting elements but also for tandem-structure light-emitting elements that require a larger driving voltage than single-structure light-emitting elements. The structure of the light-emitting element will be described later.

[0145] Furthermore, as mentioned above, the amount of current Ie flowing through the light-emitting element 61 is determined by the video signal Vdata and the Vth2 of transistor M2. In a semiconductor device 100A according to one aspect of the present invention, the amount of current Ie flowing through the light-emitting element 61 is controlled by the video signal Vdata by performing a Vth value correction operation.

[0146] Furthermore, the luminescence brightness of the light-emitting element 61 is controlled by the video signal Vdata. Therefore, it is necessary that the transistor M5 be reliably ON during light emission operation. In one aspect of the present invention, the semiconductor device 100A can be made to ensure that the transistor M5 is reliably ON during light emission operation. By using the semiconductor device 100A according to one aspect of the present invention in a display device, accurate control of the current Ie becomes possible, thereby improving the color reproduction of intermediate tones in the display device. Thus, the display quality of the display device is improved.

[0147] [Extinguishing operation] During period T16, a potential H is supplied to wiring GLd and a potential L is supplied to wiring GLc (see Figure 13). As a result, transistors M6 and M7 turn ON. This supplies a potential L from wiring GLc to node ND4. As a result, transistor M5 turns OFF. Therefore, when transistor M5 turns OFF, no current flows to the light-emitting element 61, and the light-emitting element 61 stops emitting light (extinguishing).

[0148] Display devices that use light-emitting elements, such as EL elements, as display elements can keep the light-emitting elements lit for the duration of one frame. This driving method is also called "hold type" or "hold type drive." By using hold type drive for the display device, phenomena such as screen flicker can be reduced. On the other hand, hold type drive is prone to issues such as afterimages and image blurring when displaying videos. The resolution that people perceive when displaying videos is also called "video resolution." In other words, hold type drive tends to reduce video resolution.

[0149] "Black frame insertion" is a known technique for improving issues such as motion blur and image loss in video playback. "Black frame insertion" is also called "pseudo-impulse drive" or "pseudo-impulse drive." Black frame insertion is a driving method that displays a black screen every other frame, or a driving method that displays a black screen for a certain period within a frame.

[0150] The semiconductor device 100A according to one aspect of the present invention facilitates the realization of black insertion drive through extinguishing operation. Therefore, a display device using the semiconductor device 100A according to one aspect of the present invention is less prone to a decrease in video resolution. As a result, high-quality video display is realized with the semiconductor device 100A according to one aspect of the present invention.

[0151] During the quenching operation, transistor M5 is in the off state. Therefore, even if the potential of node ND1 changes, this potential change does not interfere with the quenching operation. Also, during the Vth correction operation, transistor M5 is in the off state. Thus, although the Vth correction operation and the quenching operation were described as being in different periods in this example, the Vth correction operation may be performed during the quenching operation period.

[0152] <Drive Example 1> Next, an example of driving a display device in which a semiconductor device 100A according to one aspect of the present invention is used as a pixel of the display device will be described. As will be described in detail later, the display device has a plurality of pixels arranged in a matrix. The semiconductor device 100A may be used as a pixel of the display device. In that case, the plurality of semiconductor devices 100A may be electrically connected to the wiring DL.

[0153] For example, in the case of a display device in which pixels are arranged in a matrix of n rows and m columns (where n and m are integers greater than or equal to 1), n ​​rows of semiconductor devices 100A are electrically connected to the wiring DL. During one frame period, at least one row of the n rows of semiconductor devices 100A may be selected sequentially, and the Vth correction operation, data writing operation, light emission operation, and extinguishing operation described above may be performed on the selected semiconductor devices 100A.

[0154] Figure 14 is an example of a timing chart for explaining the driving of n rows of semiconductor devices 100A. In this embodiment, the semiconductor device 100A in row p (where p is an integer between 1 and n) may be referred to as semiconductor device 100A_p. Transistors M1 to M7 of semiconductor device 100A_p may each be referred to as transistor M1_p to transistor M7_p. Capacitors C1 to C3 of semiconductor device 100A_p may each be referred to as capacitor C1_p to capacitor C3_p. Wirings GLa, GLB, GLC, and GLD that are electrically connected to semiconductor device 100A_p may each be referred to as wiring GLa_p, wiring GLB_p, wiring GLC_p, and wiring GLD_p. Nodes ND1 to ND4 of semiconductor device 100A_p may each be referred to as node ND1_p to node ND4_p. Furthermore, the light-emitting element 61 of the semiconductor device 100A_p is sometimes referred to as the light-emitting element 61_p.

[0155] Furthermore, in Figure 14, the labels "F11," "F12_1," and "F12_2" indicate frames. The labels "1," "2," and "n" within each frame indicate the duration for which semiconductor device 100A_1, semiconductor device 100A_2, and semiconductor device 100A_n are driven, respectively. Note that the illustrations of semiconductor devices 100A_3 through 100A_n-1 are omitted.

[0156] In frame F11, n rows of semiconductor devices 100A are selected one row at a time, and a Vth correction operation is performed on the selected semiconductor devices 100A. Frames in which these operations are performed are sometimes called "correction frames". In correction frames, the potential of wiring GLa_1 to GLa_n is maintained at potential L.

[0157] First, potential H is supplied to wiring GLb_1 and wiring GLd_1, and potential L is supplied to wiring GLc_1 (corresponding to period T11). Next, potential L is supplied to wiring GLd_1, and the threshold voltage of transistor M2_1 is obtained (corresponding to period T12). Next, potential L is supplied to wiring GLb_1, and potential H is supplied to wiring GLc_1, and the obtained threshold voltage of transistor M2_1 is held in capacitor C2_1 (corresponding to period T13). Furthermore, potential H is supplied to wiring GLb_2 and wiring GLd_2, and potential L is supplied to wiring GLc_2 (corresponding to period T11). Next, potential L is supplied to wiring GLd_2, and the threshold voltage of transistor M2_2 is obtained (corresponding to period T12). Next, a potential L is supplied to wiring GLb_2 and a potential H is supplied to wiring GLc_2, so that the threshold voltage of transistor M2_2 obtained is held in capacitor C2_2 (corresponding to period T13). This operation is repeated for n rows, so that the threshold voltages of transistors M2_1 through M2_n are held in capacitors C2_1 through C2_n, respectively.

[0158] Furthermore, in both frame F12_1 and frame F12_2, n rows of semiconductor devices 100A are selected one row at a time, and data writing, illumination, and extinguishing operations are performed on the selected semiconductor devices 100A. Frame F12_2 is executed after frame F12_1. Frames in which these operations are performed are sometimes called "display frames". In display frames, the potential of wiring GLb_1 to GLb_n is maintained at potential L. Therefore, the threshold voltages of transistors M2_1 to M2_n held in capacitors C2_1 to C2_n are maintained.

[0159] In frames F12_1 and F12_2, first, a potential H is supplied to wiring GLa_1, wiring GLC_1, and wiring GLd_1, thereby supplying the video signal Vdata to node ND3_1 (corresponding to period T14). Next, a potential L is supplied to wiring GLa_1 and wiring GLd_1, causing the light-emitting element 61_1 to emit light (corresponding to period T15). Furthermore, a potential H is supplied to wiring GLa_2, wiring GLc_2, and wiring GLd_2, thereby supplying the video signal Vdata to node ND3_2 (corresponding to period T14). Next, a potential L is supplied to wiring GLa_2 and wiring GLd_2, causing the light-emitting element 61_2 to emit light (corresponding to period T15). This operation is repeated for n rows, allowing each of the light-emitting elements 61_1 through 61_n to emit light.

[0160] Furthermore, in frames F12_1 and F12_2, a potential L is supplied to wiring GLc_1 and a potential H is supplied to wiring GLd_1, thereby stopping the light emission of light-emitting element 61_1 (corresponding to period T16). Next, a potential H is supplied to wiring GLc_1 and a potential L is supplied to wiring GLd_1, maintaining the cessation of light emission from light-emitting element 61_1. Subsequently, a potential L is supplied to wiring GLc_2 and a potential H is supplied to wiring GLd_2, stopping the light emission of light-emitting element 61_2 (corresponding to period T16). Next, a potential H is supplied to wiring GLc_2 and a potential L is supplied to wiring GLd_2, maintaining the cessation of light emission from light-emitting element 61_2. This operation is repeated for n rows, thereby stopping the light emission of each of the light-emitting elements 61_1 through 61_n.

[0161] As mentioned above, the correction frame period is preferably long enough for the Vth correction operation to be performed. For example, the correction frame period is preferably 33.3 ms or longer, and more preferably 1 s or longer. In addition, to improve display quality, the display frame period is preferably short. For example, by setting the frame frequency to 120 Hz, the display frame period can be 8.33 ms. Alternatively, by setting the frame frequency to 360 Hz, the display frame period can be 2.78 ms.

[0162] In the example shown in Figure 14, the correction frame F11 is executed immediately after the display device is started, the display frame F12_1 is executed after the completion of frame F11, and the display frame F12_2 is executed after the completion of frame F12_1. Although not shown in the figure, the next display frame is executed repeatedly after the completion of frame F12_2. By executing the display frames consecutively, video display is achieved. In addition, since the correction frame is executed before the start of the display frame, a sufficient correction frame period is ensured. Therefore, the display quality of the display device is improved.

[0163] Furthermore, correction frames are executed as needed. For example, correction frames may be executed at regular intervals. For example, correction frames may be executed each time a display frame is executed an arbitrary number of times. During the correction frame period, transistor M5 is in the off state, so the extinguishing of light-emitting elements 61_1 to 61_n is maintained. Therefore, the execution of a correction frame each time a display frame is executed an arbitrary number of times may cause flickering in the display. Also, the frequency of data writing operations for display frames is reduced by the amount of the correction frame period. For this reason, a shorter correction frame period is preferable. Furthermore, a longer interval is preferable for the execution of correction frames. For example, it is preferable for a correction frame to be executed each time a display frame is executed three or more times, and it is more preferable for a correction frame to be executed each time a display frame is executed ten or more times.

[0164] Note that this example shows the Vth correction operation being performed sequentially row by row during the correction frame period, but it is not limited to this. Since the potential of the wiring DL is fixed during the correction frame period, the Vth correction operation may be performed on multiple rows simultaneously or on all rows simultaneously. Performing the Vth correction operation on multiple rows or all rows simultaneously shortens the correction frame period.

[0165] In this driving example, it is preferable that transistors M4_1 to M4_n are OS transistors. OS transistors have low off-current. Therefore, the threshold voltages of transistors M2_1 to M2_n held in capacitors C2_1 to C2_n are maintained for a long time. Thus, the number of correction frame executions is reduced.

[0166] <Drive Example 2> Figure 15 is another example of a timing chart for explaining the operation of semiconductor devices 100A_1 to 100A_n. In frames F14_1 and F14_2, n rows of semiconductor devices 100A are selected one row at a time, and data writing, illumination, and extinguishing operations are performed on the selected semiconductor devices 100A. Vth correction operations are also performed during the period in which the extinguishing operation is performed. Frames in which these operations are performed are sometimes called "display correction frames".

[0167] Furthermore, in order to improve display quality, it is preferable that the display correction frame period be short. For example, by setting the frame frequency to 120 Hz, the display correction frame period can be 8.33 ms. Alternatively, by setting the frame frequency to 360 Hz, the display correction frame period can be 2.78 ms. As will be described later, since a display correction frame is used, a separate correction frame does not need to be provided. Therefore, the frequency of data writing operations is increased. As a result, the display quality of the display device is improved.

[0168] The display correction frame is the same as the display frame described in Drive Example 1 in terms of data writing operation and light emission operation. However, the display correction frame differs from the display frame described in Drive Example 1 in that the Vth correction operation is also performed during the period in which the extinguishing operation is performed. Here, we will explain the differences from the display frame in Drive Example 1. First, when a potential L is supplied to wiring GLc_1 and a potential H is supplied to wiring GLd_1, the light emission of the light-emitting element 61_1 stops (extinguishes). Also, when a potential H is supplied to wiring GLb_1, the Vth correction operation of the semiconductor device 100A_1 starts (corresponding to period T11). Next, when a potential H is supplied to wiring GLc_1 and a potential L is supplied to wiring GLd_1, the extinguishing of the light-emitting element 61_1 is maintained. Also, when the potential of wiring GLb_1 is maintained at potential H, the threshold voltage of transistor M2_1 is obtained.

[0169] Furthermore, when a potential L is supplied to wiring GLc_2 and a potential H is supplied to wiring GLd_2, the light emission of the light-emitting element 61_2 stops. Also, when a potential H is supplied to wiring GLb_2, the Vth correction operation of the semiconductor device 100A_2 starts (corresponding to period T11). Next, when a potential H is supplied to wiring GLc_2 and a potential L is supplied to wiring GLd_2, the extinction of the light-emitting element 61_2 is maintained. Also, when the potential of wiring GLb_2 is maintained at potential H, the threshold voltage of transistor M2_2 is obtained. This operation is repeated for n rows, and the threshold voltages of transistors M2_1 through M2_n are obtained.

[0170] In the example shown in Figure 15, frame F14_1 of the display correction frame is performed, and after frame F14_1 is completed, frame F14_2 of the display correction frame is performed. Although not shown, after frame F14_2 is completed, the next display correction frame may be repeated.

[0171] For example, in the Vth correction operation of semiconductor device 100A_p, the period during which the threshold voltage of transistor M2_p is acquired can be from the start of the extinguishing operation until before the start of the data writing operation for the next display correction frame. Also, during the period during which the threshold voltage of transistor M2_p is acquired, a potential L is supplied to wiring GLa_p. Therefore, transistor M1_p is in the off state. Thus, data writing operations may be performed on semiconductor device 100A in rows other than row p.

[0172] In the display correction frame, Vth correction is performed for each frame. Therefore, even if the Vth2 of transistor M2 fluctuates during the operation of the display device, Vth correction is performed immediately. Thus, the display quality of the display device is improved. Furthermore, there is no need to set aside a separate period for Vth correction. For example, Vth correction does not need to be performed when the display device starts up. Therefore, the startup time of the display device is shortened.

[0173] The configuration shown in this embodiment can be used in appropriate combination with the configurations shown in other embodiments and examples.

[0174] (Embodiment 2) This embodiment describes a semiconductor device 100B according to one aspect of the present invention. Semiconductor device 100B is a modified example of semiconductor device 100A. Therefore, in order to reduce repetition in the explanation, we will mainly describe the differences between semiconductor device 100B and semiconductor device 100A.

[0175] <Example Configuration> Figure 16 shows an example of the circuit configuration of semiconductor device 100B. Semiconductor device 100B includes a pixel circuit 51B and a light-emitting element 61. Pixel circuit 51B differs from pixel circuit 51A in that the gates of transistor M6 and transistor M7 are electrically connected to the wiring GLa. In other words, semiconductor device 100B does not have the wiring GLd found in semiconductor device 100A. Therefore, since the formation of wiring GLd is omitted, a display device using semiconductor device 100B according to one aspect of the present invention achieves a high aperture ratio. Furthermore, high resolution is achieved. In addition, parasitic capacitance is reduced, which increases the operating speed.

[0176] <Example of operation> Next, an example of the operation of semiconductor device 100B will be explained using drawings. Figure 17 is a timing chart for illustrating an example of the operation of semiconductor device 100B. Figures 18 to 23 are circuit diagrams for illustrating an example of the operation of semiconductor device 100B.

[0177] [Vth correction operation] First, during period T21, the same reset operation as in period T11 is performed. Specifically, a potential H is supplied to wiring GLa and wiring GLB, and a potential L is supplied to wiring GLC (see Figure 18). During period T21, transistors M1, M3, M4, M6, and M7 are turned ON.

[0178] Furthermore, potential V0 is supplied to node ND1 via transistor M6. Additionally, potential V0 is supplied to node ND3 via transistors M6 and M3. Potential V1 is supplied to node ND2 via transistor M4. Potential L is supplied to node ND4 via transistor M7. Therefore, transistor M5 is in the off state.

[0179] Furthermore, during period T21, wiring DL and wiring 103 become conductive via transistors M1, M3, and M6. Therefore, during period T21, it is preferable that wiring DL and wiring 103 are at the same potential, or that wiring DL is in a floating state.

[0180] Next, during period T22, a potential L is supplied to the wiring GLa (see Figure 19). As a result, transistors M1, M6, and M7 turn off. Also, node ND4 becomes floating, and the charge supplied to node ND4 is retained, so the off state of transistor M5 is maintained. Similar to period T12 described above, the potentials of nodes ND1 and ND3 rise to the value obtained by subtracting the Vth2 of transistor M2 from the potential V1.

[0181] Next, during period T23, potential L is supplied to wiring GLb and potential H is supplied to wiring GLc (see Figure 20). As a result, transistors M3 and M4 turn off. Nodes ND1, ND2, and ND3 become floating, and the charge supplied to each node is retained. Also, the off state of transistor M5 is maintained.

[0182] [Data writing operation] During period T24, a potential H is supplied to wiring GLa (see Figure 21). Transistor M1 turns on, and the video signal Vdata is supplied to node ND3. Transistor M6 also turns on, and a potential V0 is supplied to node ND1. As with period T14 described above, the potential at node ND2 becomes Vth2.

[0183] Also, transistor M7 turns on, and charge is supplied from wiring GLc to node ND4. Similar to the period T14 described above, transistor M5 turns on, and the potential of the anode terminal of light-emitting element 61 becomes potential V0.

[0184] [Light emission operation] During period T25, a potential L is supplied to the wiring GLa (see Figure 22). Transistors M1 and M6 are then turned off. Similar to period T15 described above, current flows from wiring 101 to wiring 104, and the light-emitting element 61 emits light with a brightness corresponding to the current Ie. At this time, the potentials of node ND1 and the anode terminal of the light-emitting element 61 rise. The potential of node ND1 becomes potential Va1, and the potential of the anode terminal becomes potential Va2. Also, the potential of node ND3 becomes the video signal Vdata + potential Va1, and the potential of node ND2 becomes Vth2 + potential Va1.

[0185] Furthermore, transistor M7 turns off, and node ND4 becomes floating. Similar to the period T15 described above, when the potential of the anode terminal of the light-emitting element 61 rises from potential V0 to potential Va2, the potential of node ND4 becomes potential H - Vth7 + potential Va2. In other words, even if the potential of the anode terminal, which corresponds to the source side of transistor M5, rises, the ON state of transistor M5 is reliably maintained.

[0186] [Extinguishing operation] During period T26, a potential H is supplied to wiring GLa and a potential L is supplied to wiring GLc (see Figure 23). As a result, transistors M1, M6, and M7 turn on, the potential at node ND1 becomes potential V0, and the potential at node ND4 becomes potential L. When the potential at node ND4 becomes potential L, transistor M5 turns off, and the light emission of the light-emitting element 61 stops.

[0187] During period T26, a video signal for writing to another semiconductor device 100B electrically connected to wiring DL may be supplied to node ND3 via transistor M1. However, since transistor M5 is in the off state, this does not interfere with the extinguishing operation. Note that the video signal for writing to the other semiconductor device 100B is labeled as VdataX in Figure 23 to distinguish it from the video signal Vdata during period T24 (data writing operation).

[0188] The semiconductor device 100B, like the semiconductor device 100A, may be suitably used not only for single-structure light-emitting elements but also for tandem-structure light-emitting elements that require a higher driving voltage than single-structure elements. Furthermore, the semiconductor device 100B may perform black insertion drive, similar to the semiconductor device 100A. Therefore, a display device using the semiconductor device 100B according to one aspect of the present invention is less prone to a decrease in video resolution. Thus, a display device capable of displaying high-quality video is realized.

[0189] <Drive Example 1> Next, an example of driving a display device when a semiconductor device 100B according to one aspect of the present invention is used as a pixel in a display device will be described. Figure 24 is an example of a timing chart for explaining the driving of n rows of semiconductor devices 100B. This driving example applies driving example 1 of Embodiment 1 to driving a display device using semiconductor device 100B, and the explanation can be taken into consideration as appropriate. Here, we will mainly explain the differences between this driving example and driving example 1 of Embodiment 1.

[0190] Frame F21 is a correction frame. In frame F21, semiconductor devices 100B_1 through 100B_n are selected one row at a time, and a Vth correction operation is performed on the selected semiconductor devices 100B. First, a potential H is supplied to wiring GLa_1 and wiring GLb_1, and a potential L is supplied to wiring GLc_1 (corresponding to period T21). Next, the threshold voltage of transistor M2_1 is obtained by supplying a potential L to wiring GLa_1 (corresponding to period T22). Next, the threshold voltage of transistor M2_1 obtained is held in capacitor C2_1 by supplying a potential L to wiring GLb_1 and wiring GLc_1 (corresponding to period T23). Furthermore, a potential H is supplied to wiring GLa_2 and wiring GLb_2, and a potential L is supplied to wiring GLc_2 (corresponding to period T21). Next, a potential L is supplied to wiring GLa_2, and the threshold voltage of transistor M2_2 is obtained (corresponding to period T22). Then, a potential L is supplied to wiring GLb_2 and a potential H is supplied to wiring GLc_2, and the obtained threshold voltage of transistor M2_2 is held in capacitor C2_2 (corresponding to period T23). This operation is repeated for n rows, so that the threshold voltages of transistors M2_1 through M2_n are held in capacitors C2_1 through C2_n, respectively.

[0191] In the correction frame, the connection between wiring DL and wiring 103 is made conductive via transistors M1, M3, and M6, which are present in semiconductor devices 100B_1 to 100B_n, respectively. Therefore, during the execution of the correction frame, wiring DL may be supplied with the same potential as wiring 103, or wiring DL may be in a floating state. For example, in this embodiment, the potential V0 supplied to wiring 103 is 0V, so during the execution of the correction frame, the video signal Vdata supplied to wiring DL can be 0V (a potential corresponding to black display). Alternatively, a switch can be provided between wiring DL and the source of the video signal Vdata (e.g., a source driver), and the switch can be in a non-conductive state during the execution of the correction frame.

[0192] Frames F22_1 and F22_2 are display frames. In each of frames F22_1 and F22_2, semiconductor devices 100B_1 to 100B_n are selected one row at a time, and data writing, illumination, and extinguishing operations are performed on the selected semiconductor devices 100B. In the display frames, the potential of wiring GLb_1 to GLb_n is maintained at potential L. Therefore, the threshold voltages of transistors M2_1 to M2_n, which are held in capacitors C2_1 to C2_n, are maintained.

[0193] In frames F22_1 and F22_2, first, a potential H is supplied to wiring GLa_1 and wiring GLC_1, thereby supplying the video signal Vdata to node ND3_1 (corresponding to period T24). Next, a potential L is supplied to wiring GLa_1, causing the light-emitting element 61_1 to emit light (corresponding to period T25). Furthermore, a potential H is supplied to wiring GLa_2 and wiring GLC_2, thereby supplying the video signal Vdata to node ND3_2 (corresponding to period T24). Next, a potential L is supplied to wiring GLa_2, causing the light-emitting element 61_2 to emit light (corresponding to period T25). This operation is repeated for n rows, allowing each of the light-emitting elements 61_1 through 61_n to emit light.

[0194] Furthermore, in frames F22_1 and F22_2, a potential H is supplied to wiring GLa_1 and a potential L is supplied to wiring GLc_1, thereby stopping the light emission of light-emitting element 61_1 (corresponding to period T26). Next, a potential L is supplied to wiring GLa_1 and a potential H is supplied to wiring GLc_1, maintaining the cessation of light emission from light-emitting element 61_1. Subsequently, a potential H is supplied to wiring GLa_2 and a potential L is supplied to wiring GLc_2, stopping the light emission of light-emitting element 61_2 (corresponding to period T26). Next, a potential L is supplied to wiring GLa_2 and a potential H is supplied to wiring GLc_2, maintaining the cessation of light emission from light-emitting element 61_2. This operation is repeated for n rows, thereby stopping the light emission of each of the light-emitting elements 61_1 through 61_n.

[0195] In the driving example shown in Figure 24, frame F21 of the correction frame is performed immediately after the display device is started up, frame F22_1 of the display frame is performed after frame F21 is completed, and frame F22_2 of the display frame is performed after frame F22_1 is completed. By performing the correction frame before the display frame starts, a sufficient correction frame period is ensured. Therefore, the display quality of the display device is improved.

[0196] Correction frames are executed as needed. For example, correction frames may be executed at regular intervals. For example, correction frames may be executed each time a display frame is executed an arbitrary number of times. Note that the execution of correction frames may cause flickering in the display. Also, the frequency of data writing operations for display frames decreases by the amount of time the correction frame is performed. For this reason, a shorter correction frame period is preferable. Furthermore, a longer interval is preferable for executing correction frames.

[0197] Note that this example shows the Vth correction operation being performed sequentially row by row during the correction frame period, but it is not limited to this. Since the potential of the wiring DL is fixed during the correction frame period, the Vth correction operation may be performed on multiple rows simultaneously or on all rows simultaneously. Performing the Vth correction operation on multiple rows or all rows simultaneously shortens the correction frame period.

[0198] <Drive Example 2> Figure 25 is a timing chart illustrating other driving examples for semiconductor devices 100B_1 to 100B_n. This driving example applies driving example 2 of Embodiment 1 to the driving of a display device using semiconductor device 100B, and the explanation can be considered as appropriate. Here, we will mainly explain the differences between this driving example and driving example 2 of Embodiment 1.

[0199] Frames F24_1 and F24_2 are display correction frames. In each of frames F24_1 and F24_2, semiconductor devices 100B_1 through 100B_n are selected one row at a time, and data writing, illumination, and extinguishing operations are performed on the selected semiconductor devices 100B. In addition, if the potential of wiring DL is the same as the potential of wiring 103 during the period in which the extinguishing operation is performed, a Vth correction operation is also performed. As mentioned above, for example, in the Vth correction operation of semiconductor device 100B_p in row p (where p is an integer between 1 and n), during the reset operation (corresponding to period T21), transistors M1_p, M3_p, and M6_p are turned on, and the connection between wiring DL and wiring 103 becomes conductive (see Figure 18). Furthermore, during the period when the extinguishing operation of semiconductor device 100B_p is performed, data writing operations are performed on semiconductor device 100B in rows other than row p, so the video signal VdataX is supplied to wiring DL. In addition, the video signal VdataX supplied to wiring DL is supplied to node ND3_p via transistor M1_p (see Figure 23). For this reason, it is preferable that the Vth correction operation is performed when the video signal VdataX is at the same potential as the potential V0 supplied to wiring 103 (the potential corresponding to black display) during the period when the extinguishing operation is performed. And it is preferable that the Vth correction operation is not performed when the video signal VdataX is at a potential different from the potential V0. For example, in this embodiment, the potential V0 is 0V. Therefore, it is possible to perform the Vth correction operation when the video signal VdataX is 0V during the period when the extinguishing operation is performed, and not perform the Vth correction operation when the video signal VdataX is anything other than 0V.

[0200] Figure 25 shows, as an example, a timing chart for the case where the video signal VdataX is not 0V and the Vth correction operation of semiconductor devices 100B_1 and 100_n is not performed, in the first and nth rows, and a timing chart for the case where the video signal VdataX is 0V and the Vth correction operation of semiconductor device 100B_2 is performed, in the second row.

[0201] Figure 26 is a flowchart illustrating the operation of the display correction frame in this drive example. For clarity, Figure 26 shows the operation of the display correction frame starting with the extinguishing operation. Alternatively, the display correction frame may be repeated by starting the extinguishing operation of the next display correction frame after the completion of the illumination operation. Step S01 corresponds to period T26, step S03 to period T21, step S04 to period T24, and step S05 to period T25.

[0202] In step S01, the extinguishing operation of the semiconductor device 100B_p is initiated. Then, in step S02, it is determined whether the video signal VdataX is at the same potential as potential V0. If the determination in step S02 is YES (the video signal VdataX is at the same potential as potential V0), the Vth correction operation in step S03 is initiated, and after the completion of step S03, the data writing operation in step S04 is performed. Alternatively, if the determination in step S02 is NO (the video signal VdataX is not at the same potential as potential V0), the Vth correction operation in step S03 is not performed, and the data writing operation in step S04 is performed. After the execution of step S04, the illumination operation in step S05 is performed, and illumination is maintained until the extinguishing operation in step S01 of the next display correction frame.

[0203] Furthermore, when a semiconductor device 100B according to one aspect of the present invention is used as a pixel in a display device, for example, the semiconductor devices 100B are arranged in a matrix of n rows and m columns (where n and m are integers of 1 or more), and m columns of semiconductor devices 100B are connected to wiring GLa, wiring GLb, and wiring GLc in each row. Therefore, extinguishing and Vth correction operations are performed simultaneously for all m columns of semiconductor devices 100B in each row. Thus, if all of the video signals VdataX supplied to each of the m columns of wiring DL are 0V (potential corresponding to black display), the Vth correction operation can be said to be performed. Alternatively, if at least one of the video signals VdataX supplied to each of the m columns of wiring DL is not 0V (potential corresponding to black display), the Vth correction operation can be said not to be performed.

[0204] In Figure 25, first, a potential H is supplied to wiring GLa_1 and a potential L is supplied to wiring GLc_1, causing the light-emitting element 61_1 to stop emitting light (extinction). Also, by maintaining the potential of wiring GLb_1 at potential L, the Vth correction operation of semiconductor device 100B_1 is not performed. Next, a potential L is supplied to wiring GLa_1 and a potential H is supplied to wiring GLc_1, maintaining the extinction of the light-emitting element 61_1.

[0205] Furthermore, when a potential H is supplied to wiring GLa_2 and a potential L is supplied to wiring GLc_2, the light emission of the light-emitting element 61_2 stops. Also, when a potential H is supplied to wiring GLb_2, the Vth correction operation of the semiconductor device 100B_2 starts (corresponding to period T21). Next, when a potential L is supplied to wiring GLa_2 and a potential H is supplied to wiring GLc_2, the extinction of the light-emitting element 61_2 is maintained. Also, when the potential of wiring GLb_2 is maintained at potential H, the threshold voltage of transistor M2_2 is obtained.

[0206] Thus, for example, in semiconductor device 100B_p, when Vth correction operation is performed, a potential H is supplied to wiring GLb_p, and when Vth correction operation is not performed, the potential of wiring GLb_p is maintained at potential L. This operation is repeated for n rows, and the threshold voltage of transistor M2 is acquired only for rows where the video signal VdataX is at the same potential as potential V0 (the potential corresponding to black display). Furthermore, the period during which the threshold voltage of transistor M2_p is acquired may be set from the start of the extinguishing operation until before the start of the data writing operation for the next display correction frame.

[0207] In the drive example shown in Figure 25, frame F24_1 of the display correction frame is performed, and after frame F24_1 is completed, frame F24_2 of the display correction frame is performed. Although not shown, the next display correction frame may be repeated after frame F24_2 is completed. Therefore, a separate correction frame is not required. Thus, the frequency of data writing operations can be increased. As a result, the display quality of the display device can be improved.

[0208] The configuration shown in this embodiment can be used in appropriate combination with the configurations shown in other embodiments and examples.

[0209] (Embodiment 3) This embodiment describes an example configuration of a display device 10 using a semiconductor device 100 (semiconductor device 100A or semiconductor device 100B). Figure 27A is a block diagram illustrating the display device 10. The display device 10 has a display area 235, a first drive circuit unit 231, and a second drive circuit unit 232. The display area 235 has a plurality of pixels 230 arranged in a matrix. A semiconductor device 100 according to one aspect of the present invention may be used for the pixels 230.

[0210] The circuits included in the first drive circuit section 231 function, for example, as a scan line drive circuit. The circuits included in the second drive circuit section 232 function, for example, as a signal line drive circuit. Some circuits may be provided at a position facing the first drive circuit section 231 across the display area 235. Some circuits may also be provided at a position facing the second drive circuit section 232 across the display area 235. In this specification, the circuits included in the first drive circuit section 231 and the second drive circuit section 232 are sometimes collectively referred to as "peripheral drive circuits."

[0211] Various circuits can be used in the peripheral drive circuit, such as shift registers, level shifters, inverters, latches, analog switches, or logic circuits. Transistors or capacitive elements can also be used in the peripheral drive circuit.

[0212] For example, OS transistors may be used in the transistors constituting the pixel 230, and Si transistors may be used in the transistors constituting the peripheral drive circuit. OS transistors have a low off-current. Therefore, the power consumption of the pixel 230 using OS transistors can be reduced. Si transistors have a faster operating speed than OS transistors. Therefore, Si transistors are suitably used in peripheral drive circuits. In addition, depending on the display device, OS transistors may be used in both the transistors constituting the pixel 230 and the transistors constituting the peripheral drive circuit. In addition, depending on the display device, Si transistors may be used in both the transistors constituting the pixel 230 and the transistors constituting the peripheral drive circuit. In addition, depending on the display device, Si transistors may be used in the transistors constituting the pixel 230, and OS transistors may be used in the transistors constituting the peripheral drive circuit.

[0213] Furthermore, both Si transistors and OS transistors may be used in the transistors constituting the pixel 230. Also, both Si transistors and OS transistors may be used in the transistors constituting the peripheral drive circuit.

[0214] Furthermore, the display device 10 has m wires 236, each arranged substantially parallel to the others, and whose potential is controlled by a circuit included in the first drive circuit section 231. The display device 10 also has n wires 237, each arranged substantially parallel to the others, and whose potential is controlled by a circuit included in the second drive circuit section 232.

[0215] Figure 27A shows an example where wiring 236 and wiring 237 are connected to pixel 230. However, Figure 27A is just one example, and the wiring connected to pixel 230 is not limited to wiring 236 and wiring 237.

[0216] A full-color display device 10 can be realized by combining the pixels 230 that control red light, the pixels 230 that control green light, and the pixels 230 that control blue light into a single pixel 240, and by controlling the amount of light emitted (luminescence) of each pixel 230. Thus, each of the three pixels 230 functions as a sub-pixel. That is, each of the three sub-pixels controls, for example, the amount of red light emitted, the amount of green light emitted, or the amount of blue light emitted (see Figure 27B). Note that the colors of light controlled by each of the three sub-pixels are not limited to the combination of red (R), green (G), and blue (B), but may also be the combination of cyan (C), magenta (M), and yellow (Y) (see Figure 27C).

[0217] Furthermore, the arrangement of the three pixels 230 that make up one pixel 240 may be a delta arrangement (see Figure 27D). Specifically, the three pixels 230 that make up one pixel 240 may be arranged such that the line connecting the center points of each pixel 230 forms a triangle.

[0218] Furthermore, the areas of the three subpixels (pixel 230) do not have to be the same. If, for example, the luminous efficiency and reliability differ depending on the emission color, the area of ​​each of the three subpixels may be changed for each emission color (see Figure 27E). The subpixel arrangement shown in Figure 27E may be called, for example, the "S-Stripe RGB arrangement".

[0219] Alternatively, the four subpixels may be combined and function as a single pixel 240. For example, a subpixel controlling white light may be added to the three subpixels that control red, green, and blue light respectively (see Figure 27F). By adding a subpixel that controls white light, a display device 10 with increased brightness of the display area 235 can be realized. Alternatively, a subpixel that controls yellow light may be added to the three subpixels that control red, green, and blue light respectively (see Figure 27G). Alternatively, a subpixel that controls white light may be added to the three subpixels that control cyan, magenta, and yellow light respectively (see Figure 27H).

[0220] Furthermore, by increasing the number of subpixels that function as a single pixel in pixel 240, and by appropriately combining subpixels that control light such as red, green, blue, cyan, magenta, and yellow, a display device 10 with improved reproduction of halftones can be realized. Thus, a display device 10 with improved display quality can be realized.

[0221] A display device 10 according to one aspect of the present invention can reproduce a variety of color gamuts. For example, it can reproduce color gamuts such as the PAL (Phase Alternating Line) standard or NTSC (National Television System Committee) standard used in television broadcasting, the sRGB (standard RGB) standard or Adobe RGB standard widely used in display devices for electronic devices such as personal computers, digital cameras, or printers, the ITU-R BT.709 (International Telecommunication Union Radiocommunication Sector Broadcasting Service (Television) 709) standard used in HDTV (High Definition Television), the DCI-P3 (Digital Cinema Initiatives P3) standard used in digital cinema projection, or the ITU-R BT.2020 (REC.2020 (Recommendation 2020)) standard used in UHDTV (Ultra High Definition Television).

[0222] Furthermore, by arranging 240 pixels in a 1920 x 1080 matrix, a display device 10 capable of full-color display at a resolution known as Full HD (also known as "2K resolution," "2K1K," or "2K"). Furthermore, by arranging 240 pixels in a 3840 x 2160 matrix, a display device 10 capable of full-color display at a resolution known as Ultra HD (also known as "4K resolution," "4K2K," or "4K"). Furthermore, by arranging 240 pixels in a 7680 x 4320 matrix, a display device 10 capable of full-color display at a resolution known as Super Hi-Vision (also known as "8K resolution," "8K4K," or "8K"). Additionally, by increasing the number of pixels, it is possible to realize a display device 10 capable of full-color display at a resolution of 16K or 32K.

[0223] Furthermore, the pixel density of the display area 235 is preferably 100 ppi or more and 10,000 ppi or less, and more preferably 1,000 ppi or more and 10,000 ppi or less. For example, the pixel density of the display area 235 may be 2,000 ppi or more and 6,000 ppi or less, or 3,000 ppi or more and 5,000 ppi or less.

[0224] Furthermore, the aspect ratio of the display area 235 is not particularly limited. The display area 235 of the display device 10 can support various aspect ratios, such as 1:1 (square), 4:3, 16:9, and 16:10.

[0225] Furthermore, the diagonal size of the display area 235 may be 0.1 inches or more and 100 inches or less, or it may be 100 inches or more.

[0226] When the display device 10 is used as a display device for virtual reality (VR) or augmented reality (AR), the diagonal size of the display area 235 can be set to 0.1 inches or more and 5.0 inches or less, preferably 0.5 inches or more and 2.0 inches or less, and more preferably 1 inch or more and 1.7 inches or less. For example, the diagonal size of the display area 235 may be 1.5 inches or near 1.5 inches. By setting the diagonal size of the display area 235 to 2.0 inches or less, preferably near 1.5 inches, it becomes possible to complete the exposure process performed by an exposure device (typically a scanner device) in one time, and thus the productivity of the manufacturing process can be improved.

[0227] Also, according to the diagonal size of the display area 235, the configuration of the transistor used for the display area 235 may be appropriately selected. For example, when a single crystal Si transistor is used for the display area 235, the diagonal size of the display area 235 is preferably 0.1 inches or more and 3 inches or less. Also, when an LTPS transistor is used for the display area 235, the diagonal size of the display area 235 is preferably 0.1 inches or more and 30 inches or less, and more preferably 1 inch or more and 30 inches or less. Also, when an LTPO (a configuration in which an LTPS transistor and an OS transistor are combined) is used for the display area 235, the diagonal size of the display area 235 is preferably 0.1 inches or more and 50 inches or less, and more preferably 1 inch or more and 50 inches or less. Also, when an OS transistor is used for the display area 235, the diagonal size of the display area 235 is preferably 0.1 inches or more and 200 inches or less, and more preferably 50 inches or more and 100 inches or less.

[0228] Due to the size of the single-crystalline Si substrate, it is very difficult to increase the size of the display panel. Also, since an LTPS transistor uses a laser crystallization device in the manufacturing process, it is difficult to handle large-sized display panels (typically, a screen size exceeding 30 inches in diagonal size). On the other hand, an OS transistor has no restrictions such as using a laser crystallization device in the manufacturing process, or it can be manufactured at a relatively low process temperature (typically 450°C or lower), so it can handle display panels with a relatively large area (typically, a diagonal size of 50 inches or more and 100 inches or less). Also, LTPO can be applied to the size of the display panel (typically, a diagonal size of 1 inch or more and 50 inches or less) in the area between the case of using an LTPS transistor and the case of using an OS transistor.

[0229] <Configuration Example of Light-Emitting Element> A light-emitting element (also referred to as a light-emitting device) that can be used in a semiconductor device according to an aspect of the present invention will be described.

[0230] As shown in FIG. 28A, the light-emitting element 61 includes an EL layer 172 between a pair of electrodes (conductive layer 171 and conductive layer 173). The EL layer 172 can be composed of a plurality of layers such as, for example, layer 4420, light-emitting layer 4411, and layer 4430. The layer 4420 can include, for example, a layer containing a substance with high electron injection property (electron injection layer) and a layer containing a substance with high electron transport property (electron transport layer). The light-emitting layer 4411 includes, for example, a light-emitting compound. The layer 4430 can include, for example, a layer containing a substance with high hole injection property (hole injection layer) and a layer containing a substance with high hole transport property (hole transport layer).

[0231] The configuration including the layer 4420, light-emitting layer 4411, and layer 4430 provided between a pair of electrodes can function as a single light-emitting unit. In this specification and the like, the configuration of FIG. 28A is referred to as a single structure.

[0232] Furthermore, Figure 28B shows a modified example of the EL layer 172 of the light-emitting element 61 shown in Figure 28A. Specifically, the light-emitting element 61 shown in Figure 28B comprises a layer 4430-1 on the conductive layer 171, a layer 4430-2 on layer 4430-1, a light-emitting layer 4411 on layer 4430-2, a layer 4420-1 on the light-emitting layer 4411, a layer 4420-2 on layer 4420-1, and a conductive layer 173 on layer 4420-2. For example, when the conductive layer 171 is the anode and the conductive layer 173 is the cathode, layer 4430-1 functions as a hole injection layer, layer 4430-2 functions as a hole transport layer, layer 4420-1 functions as an electron transport layer, and layer 4420-2 functions as an electron injection layer. Alternatively, if conductive layer 171 is used as the cathode and conductive layer 173 as the anode, layer 4430-1 functions as an electron injection layer, layer 4430-2 functions as an electron transport layer, layer 4420-1 functions as a hole transport layer, and layer 4420-2 functions as a hole injection layer. By having such a layer structure, the light-emitting element 61 can efficiently inject carriers into the light-emitting layer 4411 and improve the efficiency of carrier recombination within the light-emitting layer 4411.

[0233] As shown in Figure 28C, a configuration in which multiple light-emitting layers (light-emitting layer 4411, light-emitting layer 4412, and light-emitting layer 4413) are provided between layer 4420 and layer 4430 is also an example of a single structure.

[0234] Furthermore, as shown in Figure 28D, a configuration in which multiple light-emitting units (EL layers 172a and EL layers 172b) are connected in series via an intermediate layer (charge generation layer) 4440 is referred to in this specification as a tandem structure or stack structure. By using a tandem structure for the light-emitting element 61, a light-emitting element 61 capable of high-brightness light emission can be realized.

[0235] Furthermore, if the light-emitting element 61 is in the tandem structure shown in Figure 28D, the light-emitting colors of the EL layer 172a and EL layer 172b may be the same. For example, the light-emitting colors of both the EL layer 172a and EL layer 172b may be green. Note that if the display area 235 includes three sub-pixels R, G, and B, and each sub-pixel is equipped with a light-emitting element, the light-emitting elements of each sub-pixel may be in a tandem structure. Specifically, the EL layer 172a and EL layer 172b of the R sub-pixel each have a material capable of emitting red light. The EL layer 172a and EL layer 172b of the G sub-pixel each have a material capable of emitting green light. The EL layer 172a and EL layer 172b of the B sub-pixel each have a material capable of emitting blue light. In other words, the materials of the light-emitting layer 4411 and the light-emitting layer 4412 may be the same. The tandem-structured light-emitting element 61 shown in Figure 28D can reduce the current density per unit luminous intensity by making the light-emitting color of the EL layer 172a and EL layer 172b the same. Therefore, the reliability of the light-emitting element 61 can be improved.

[0236] The light-emitting color of the light-emitting element can be, for example, red, green, blue, cyan, magenta, yellow, or white, depending on the material constituting the EL layer 172. Furthermore, the color purity of the light-emitting element can be further enhanced by adding a microcavity structure.

[0237] The light-emitting layer may contain two or more light-emitting materials that emit light such as R (red), G (green), B (blue), Y (yellow), or O (orange). For a light-emitting element that emits white light, it is preferable to have a configuration in which the light-emitting layer contains two or more types of light-emitting materials. In one aspect of the present invention, when obtaining white light emission using two types of light-emitting materials, the light-emitting materials should be selected such that the colors of the light emitted by each of the two materials are complementary colors. For example, in one aspect of the present invention, the light-emitting element can emit white light as a whole by ensuring that the light-emitting color of the first light-emitting material and the light-emitting color of the second light-emitting material are complementary colors. Furthermore, in one aspect of the present invention, when obtaining white light emission using three or more types of light-emitting materials, the light-emitting element can emit white light as a whole by combining the colors of the light emitted by each of the three or more light-emitting materials.

[0238] Furthermore, it is preferable that the light-emitting layer has two or more light-emitting materials, and that the light emitted by each light-emitting material includes two or more spectral components of colors from R, G, and B.

[0239] Examples of luminescent materials include fluorescent materials, phosphorescent materials, inorganic compounds (such as quantum dot materials), and thermally activated delayed fluorescence (TADF) materials. For TADF materials, materials in thermal equilibrium between the singlet and triplet excited states may also be used. Such TADF materials have a shorter emission lifetime (excitation lifetime), which helps suppress efficiency degradation in the high-brightness region of the light-emitting element.

[0240] <Method for forming light-emitting elements> The following describes an example of a method for forming the light-emitting element 61.

[0241] Figure 29A is a schematic top view of the light-emitting element 61. The light-emitting element 61 has multiple red light-emitting elements 61R, multiple green light-emitting elements 61G, and multiple blue light-emitting elements 61B. In Figure 29A, the labels R, G, and B are added within the light-emitting area of ​​each light-emitting element for easy distinction. The configuration of the light-emitting element 61 shown in Figure 29A may also be called an SBS (Side By Side) structure. Furthermore, although Figure 29A illustrates a configuration having three colors of light-emitting elements 61: red (R), green (G), and blue (B), the invention is not limited to this. One aspect of the present invention may be a configuration having four or more colors of light-emitting elements 61.

[0242] The light-emitting elements 61R, 61G, and 61B are each arranged in a matrix. Figure 29A shows a so-called stripe arrangement in which light-emitting elements of the same color are arranged in one direction, but the arrangement method of the light-emitting elements is not limited to this. Examples of arrangement methods for the light-emitting elements include delta arrangement, zigzag arrangement, S-Stripe RGB arrangement, or pentile arrangement.

[0243] It is preferable to use organic EL devices such as OLED (Organic Light Emitting Diode) or QOLED (Quantum-dot Organic Light Emitting Diode) as the light-emitting elements 61R, 61G, and 61B. Examples of light-emitting materials for the EL elements include fluorescent materials, phosphorescent materials, inorganic compounds (such as quantum dot materials), or thermally activated delayed fluorescence (TADF) materials.

[0244] Figure 29B is a schematic cross-sectional view corresponding to the dashed line A1-A2 in Figure 29A. Figure 29B shows cross-sections of the light-emitting element 61R, light-emitting element 61G, and light-emitting element 61B. The light-emitting elements 61R, 61G, and 61B are each provided on an insulating layer 363. The light-emitting elements 61R, 61G, and 61B have a conductive layer 171 that functions as a pixel electrode and a conductive layer 173 that functions as a common electrode. One or both of an inorganic insulating film and an organic insulating film can be used as the insulating layer 363. It is preferable to use an inorganic insulating film as the insulating layer 363. Examples of inorganic insulating films include oxide insulating films or nitride insulating films such as silicon oxide film, silicon oxide nitride film, silicon nitride film, silicon nitride film, aluminum oxide film, aluminum oxide nitride film, or hafnium oxide film.

[0245] The light-emitting element 61R has an EL layer 172R between a conductive layer 171 that functions as a pixel electrode and a conductive layer 173 that functions as a common electrode. The EL layer 172R has a luminescent organic compound that emits light with intensity in at least the red wavelength range. The EL layer 172G of the light-emitting element 61G has a luminescent organic compound that emits light with intensity in at least the green wavelength range. The EL layer 172B of the light-emitting element 61B has a luminescent organic compound that emits light with intensity in at least the blue wavelength range.

[0246] Each of the EL layers 172R, 172G, and 172B may have, in addition to a layer containing a luminescent organic compound (luminescent layer), one or more of the following: an electron injection layer, an electron transport layer, a hole injection layer, and a hole transport layer.

[0247] The conductive layer 171 that functions as a pixel electrode is provided for each light-emitting element. Also, the conductive layer 173 that functions as a common electrode is provided as a continuous layer common to each light-emitting element. A conductive film having translucency with respect to visible light is used for either one of the conductive layer 171 that functions as a pixel electrode or the conductive layer 173 that functions as a common electrode, and a conductive film having reflectivity is used for the other. The display device according to one aspect of the present invention can be a bottom emission type display device by making the conductive layer 171 that functions as a pixel electrode translucent and making the conductive layer 173 that functions as a common electrode reflective. Or, the display device according to one aspect of the present invention can be a top emission type display device by making the conductive layer 171 that functions as a pixel electrode reflective and making the conductive layer 173 that functions as a common electrode translucent. Note that the display device according to one aspect of the present invention can also be a dual emission type display device by making both the conductive layer 171 that functions as a pixel electrode and the conductive layer 173 that functions as a common electrode translucent.

[0248] For example, when the light-emitting element 61R is of the top emission type, the light 175R emitted from the light-emitting element 61R is emitted toward the conductive layer 173 side. When the light-emitting element 61G is of the top emission type, the light 175G emitted from the light-emitting element 61G is emitted toward the conductive layer 173 side. When the light-emitting element 61B is of the top emission type, the light 175B emitted from the light-emitting element 61B is emitted toward the conductive layer 173 side.

[0249] The insulating layer 272 is provided so as to cover the end portion of the conductive layer 171 that functions as a pixel electrode. The end portion of the insulating layer 272 is preferably in a tapered shape. A material similar to the material used for the insulating layer 363 can be used for the insulating layer 272.

[0250] The insulating layer 272 is provided to prevent adjacent light-emitting elements 61 from unintentionally short-circuiting and emitting false light. The insulating layer 272 also has the function of preventing the metal mask from coming into contact with the conductive layer 171 when a metal mask is used to form the EL layer 172.

[0251] Each of the EL layers 172R, 172G, and 172B has a region in contact with the upper surface of the conductive layer 171, which functions as a pixel electrode, and a region in contact with the surface of the insulating layer 272. The edges of the EL layers 172R, 172G, and 172B are located on the insulating layer 272.

[0252] As shown in Figure 29B, a gap is provided between the EL layers of the light-emitting element exhibiting two different colors. In this way, it is preferable that the EL layers 172R, 172G, and 172B are arranged so that they do not touch each other. This effectively prevents current from flowing through two adjacent EL layers and causing unintended light emission (also known as crosstalk). Therefore, one aspect of the present invention can enhance contrast and realize a display device with high display quality.

[0253] The EL layer 172R, EL layer 172G, and EL layer 172B can be differentiated by, for example, a vacuum deposition method using a shadow mask such as a metal mask. Alternatively, they may be differentiated by photolithography. In one aspect of the present invention, by using photolithography, a display device with high resolution, which is difficult to achieve when using a metal mask, can be realized.

[0254] In this specification, devices fabricated using a metal mask or FMM (Fine Metal Mask, a high-resolution metal mask) may be referred to as MM (Metal Mask) structured devices. Furthermore, in this specification, devices fabricated without using a metal mask or FMM may be referred to as MML (Metal Maskless) structured devices. Because MML structured display devices are fabricated without a metal mask, they offer greater design flexibility in terms of pixel arrangement and pixel shape compared to MM structured display devices.

[0255] A protective layer 271 is provided on the conductive layer 173, which functions as a common electrode, covering the light-emitting elements 61R, 61G, and 61B. The protective layer 271 has the function of preventing impurities, such as water, from diffusing to each light-emitting element from above.

[0256] The protective layer 271 can be a single-layer or multilayer structure, for example, including at least an inorganic insulating film. Examples of the inorganic insulating film include oxide films or nitride films such as silicon oxide film, silicon oxide nitride film, silicon nitride film, silicon nitride film, aluminum oxide film, aluminum oxide nitride film, or hafnium oxide film. Alternatively, semiconductor materials such as indium gallium oxide or indium gallium zinc oxide (IGZO) may be used as the protective layer 271. The protective layer 271 may be formed, for example, by ALD, CVD, or sputtering. Although the example shows the protective layer 271 including an inorganic insulating film, it is not limited to this. For example, the protective layer 271 may be a multilayer structure of an inorganic insulating film and an organic insulating film.

[0257] In this specification, compounds with a nitrogen content greater than oxygen content are referred to as nitride oxides. Compounds with a nitrogen content greater than nitrogen content are referred to as oxiditrides. The content of each element can be measured, for example, using Rutherford backscattering spectrometry (RBS).

[0258] The protective layer 271 can be processed using either a wet etching method or a dry etching method when using indium gallium zinc oxide. For example, when using IGZO, the protective layer 271 can be processed using chemicals such as oxalic acid, phosphoric acid, or a mixed chemical solution (for example, a mixed chemical solution of phosphoric acid, acetic acid, nitric acid, and water (also called a mixed aluminum etchant)). The mixed aluminum etchant can be formulated in a volume ratio of approximately phosphoric acid:acetic acid:nitric acid:water = 53.3:6.7:3.3:36.7.

[0259] Figure 29C shows a different example from the one described above. Specifically, in Figure 29C, the light-emitting element 61 has a light-emitting element 61W that emits white light. The light-emitting element 61W has an EL layer 172W that emits white light between a conductive layer 171 that functions as a pixel electrode and a conductive layer 173 that functions as a common electrode.

[0260] The EL layer 172W can be configured, for example, by stacking two light-emitting layers selected so that their respective light-emitting colors are complementary. Alternatively, a stacked EL layer with a charge-generating layer sandwiched between the light-emitting layers may be used.

[0261] Figure 29C shows three light-emitting elements 61W arranged side by side. A colored layer 264R is provided on top of the left light-emitting element 61W. The colored layer 264R functions as a bandpass filter that transmits red light. Similarly, a colored layer 264G that transmits green light is provided on top of the center light-emitting element 61W. Similarly, a colored layer 264B that transmits blue light is provided on top of the right light-emitting element 61W. This allows the display device to display a color image.

[0262] Here, the EL layer 172W and the conductive layer 173, which functions as a common electrode, are separated between two adjacent light-emitting elements 61W. This prevents unintended light emission from occurring due to current flowing through the EL layer 172W between two adjacent light-emitting elements 61W. In particular, when a stacked EL layer with a charge generation layer between two light-emitting layers is used as the EL layer 172W, the higher the resolution, i.e., the smaller the distance between adjacent pixels, the more pronounced the crosstalk effect becomes, resulting in a decrease in contrast. Therefore, one aspect of the present invention, by adopting such a configuration, can realize a display device that combines high resolution and high contrast.

[0263] The separation of the EL layer 172W and the conductive layer 173, which functions as a common electrode, is preferably performed by photolithography. This allows the spacing between light-emitting elements to be reduced. Therefore, one aspect of the present invention can realize a display device with a high aperture ratio compared to the case in which a shadow mask such as a metal mask is used.

[0264] In one aspect of the present invention, in the case of a bottom-emission type light-emitting element, a colored layer may be provided between the conductive layer 171, which functions as a pixel electrode, and the insulating layer 363.

[0265] Figure 29D shows an example different from the above. Specifically, Figure 29D shows a configuration in which the insulating layer 272 is not provided between the light-emitting element 61R, light-emitting element 61G, and light-emitting element 61B. By adopting this configuration, the display device according to one aspect of the present invention can be made into a display device with a high aperture ratio. Furthermore, by not providing the insulating layer 272, the unevenness of the light-emitting element 61 is reduced, so the display device according to one aspect of the present invention can be made into a display device with a wide viewing angle. Specifically, the display device according to one aspect of the present invention can make the viewing angle 150° or more and less than 180°, preferably 160° or more and less than 180°, more preferably 160° or more and less than 180°.

[0266] Furthermore, the protective layer 271 covers the sides of the EL layers 172R, 172G, and 172B. In one aspect of the present invention, this configuration can suppress impurities (typically water, etc.) that may enter from the sides of the EL layers 172R, 172G, and 172B. As a result, leakage current between adjacent light-emitting elements 61 is reduced. Therefore, the display device according to one aspect of the present invention has improved saturation and contrast ratio, and reduced power consumption.

[0267] Furthermore, in the configuration shown in Figure 29D, the top surface shapes of the conductive layer 171, the EL layer 172R, and the conductive layer 173 are roughly identical. Such a structure can be formed all at once after the conductive layer 171, the EL layer 172R, and the conductive layer 173 have been formed, for example, using a resist mask. This process can also be called self-aligned patterning, as it involves processing the EL layer 172R and the conductive layer 173 using the conductive layer 173 as a mask. Although the EL layer 172R has been described here, the EL layer 172G and the EL layer 172B can also be constructed in a similar manner.

[0268] Furthermore, in Figure 29D, a protective layer 273 is provided on top of the protective layer 271. For example, the protective layer 271 can be formed using an apparatus capable of forming a highly covering film (typically an ALD apparatus, etc.), and the protective layer 273 can be formed using an apparatus capable of forming a film with lower covering properties than the protective layer 271 (typically a sputtering apparatus, etc.). By forming the protective layer 271 and the protective layer 273, a region 275 can be provided between the protective layer 271 and the protective layer 273. In other words, the region 275 is located between the EL layer 172R and the EL layer 172G, and between the EL layer 172G and the EL layer 172B.

[0269] Region 275 contains one or more elements selected from, for example, air, nitrogen, oxygen, carbon dioxide, and Group 18 elements (typically helium, neon, argon, xenon, and krypton). Region 275 may also contain, for example, the gas used when depositing the protective layer 273. For example, when depositing the protective layer 273 by sputtering, region 275 may contain one or more of the above-mentioned Group 18 elements. If region 275 contains a gas, that gas can be identified, for example, by gas chromatography. Furthermore, when depositing the protective layer 273 by sputtering, the gas used during sputtering may also be present in the protective layer 273 film. In this case, when the protective layer 273 is analyzed, for example, by energy-dispersive X-ray analysis (EDX analysis), elements such as argon may be detected.

[0270] Furthermore, if the refractive index of region 275 is lower than that of the protective layer 271, light emitted from EL layer 172R, EL layer 172G, or EL layer 172B will be reflected at the interface between the protective layer 271 and region 275. This can suppress the incidence of light emitted from EL layer 172R, EL layer 172G, or EL layer 172B onto adjacent pixels. This suppresses the mixing of different emission colors from neighboring pixels, thereby improving the display quality of the display device.

[0271] In the configuration shown in Figure 29D, the region between the light-emitting element 61R and the light-emitting element 61G, or the region between the light-emitting element 61G and the light-emitting element 61B (hereinafter simply referred to as the distance between light-emitting elements), can be narrowed. Specifically, the distance between light-emitting elements can be 1 μm or less, preferably 500 nm or less, and more preferably 200 nm or less, 100 nm or less, 90 nm or less, 70 nm or less, 50 nm or less, 30 nm or less, 20 nm or less, 15 nm or less, or 10 nm or less. In other words, the configuration shown in Figure 29D has a region where the gap between the side surface of the EL layer 172R and the side surface of the EL layer 172G, or the gap between the side surface of the EL layer 172G and the side surface of the EL layer 172B, is 1 μm or less, preferably 0.5 μm (500 nm) or less, and more preferably 100 nm or less.

[0272] Furthermore, in the configuration shown in Figure 29D, for example, when region 275 contains a gas, it is possible to isolate the light-emitting elements while suppressing, for example, color mixing or crosstalk of light from each light-emitting element.

[0273] Furthermore, region 275 may be filled with a filler. Examples of fillers include epoxy resin, acrylic resin, silicone resin, phenolic resin, polyimide resin, imide resin, PVC (polyvinyl chloride) resin, PVB (polyvinyl butyral) resin, or EVA (ethylene vinyl acetate) resin. Alternatively, a photoresist may be used as a filler. The photoresist used as a filler may be a positive-type photoresist or a negative-type photoresist.

[0274] Furthermore, when comparing the above-mentioned white light-emitting devices (single or tandem structure) with light-emitting devices with an SBS structure, the light-emitting devices with an SBS structure can consume less power than the white light-emitting devices. Therefore, in a display device according to one aspect of the present invention, it is preferable to use a light-emitting device with an SBS structure when it is desirable to keep power consumption low. On the other hand, the manufacturing process for white light-emitting devices is simpler than that for light-emitting devices with an SBS structure. Therefore, by suitably using a white light-emitting device, the display device according to one aspect of the present invention can reduce manufacturing costs or increase manufacturing yield.

[0275] Figure 30A shows an example different from the above. Specifically, the configuration shown in Figure 30A differs from the configuration shown in Figure 29D in the configuration of the insulating layer 363. When the light-emitting elements 61R, 61G, and 61B are processed, a portion of the upper surface of the insulating layer 363 is scraped away, creating a recess. The protective layer 271 is formed in this recess. In other words, in a cross-sectional view, the configuration shown in Figure 30A has a region where the lower surface of the protective layer 271 is lower than the lower surface of the conductive layer 171. The configuration shown in Figure 30A, by having this region, can suitably suppress impurities (typically water, etc.) that may enter the light-emitting elements 61R, 61G, and 61B from below. The above-mentioned recess may be formed when impurities (also called residues) that may adhere to the sides of each light-emitting element are removed during the processing of the light-emitting elements 61R, 61G, and 61B, for example, by wet etching. In one aspect of the present invention, a highly reliable display device can be obtained by removing the above-mentioned residue and then covering the sides of each light-emitting element with a protective layer 271.

[0276] Figure 30B shows an example different from the above. Specifically, the configuration shown in Figure 30B includes an insulating layer 276 and a microlens array 277 in addition to the configuration shown in Figure 30A. The insulating layer 276 functions as an adhesive layer. When the refractive index of the insulating layer 276 is lower than that of the microlens array 277, the microlens array 277 can concentrate the light emitted from the light-emitting elements 61R, 61G, and 61B. As a result, the configuration shown in Figure 30B can improve the light extraction efficiency of the display device. In particular, it is preferable because a bright image can be viewed when the user views the display surface of the display device from the front. Various types of curing adhesives can be used as the insulating layer 276, such as UV-curing adhesives, reaction-curing adhesives, thermosetting adhesives, or anaerobic adhesives. Examples of these adhesives include epoxy resins, acrylic resins, silicone resins, phenolic resins, polyimide resins, imide resins, PVC (polyvinyl chloride) resins, PVB (polyvinyl butyral) resins, or EVA (ethylene vinyl acetate) resins. Materials with low moisture permeability, such as epoxy resins, are particularly preferred. Two-component mixed resins may also be used. Adhesive sheets, for example, may also be used.

[0277] Figure 30C shows a different example from the above. Specifically, the configuration shown in Figure 30C has three light-emitting elements 61W instead of the light-emitting elements 61R, 61G, and 61B in the configuration shown in Figure 30A. Also, the configuration shown in Figure 30C has an insulating layer 276 above the three light-emitting elements 61W. Furthermore, the configuration shown in Figure 30C has colored layers 264R, 264G, and 264B above the insulating layer 276. Specifically, the colored layer 264R, which transmits red light, is positioned to overlap with the left light-emitting element 61W. The colored layer 264G, which transmits green light, is positioned to overlap with the central light-emitting element 61W. The colored layer 264B, which transmits blue light, is positioned to overlap with the right light-emitting element 61W. As a result, the display device can display a color image. Note that the configuration shown in Figure 30C is also a modified version of the configuration shown in Figure 29C.

[0278] Figure 30D shows an example different from the above. Specifically, in the configuration shown in Figure 30D, the protective layer 271 is provided adjacent to the sides of the conductive layer 171 and the EL layer 172. The conductive layer 173 is provided as a continuous layer common to each light-emitting element. In addition, in the configuration shown in Figure 30D, it is preferable that region 275 is filled with a filler material.

[0279] A light-emitting element 61 according to one aspect of the present invention can enhance the color purity of the emitted light by providing a microcavity structure. When providing a microcavity structure to the light-emitting element 61, the light-emitting element 61 should be configured such that the product of the distance d between the conductive layer 171 and the conductive layer 173 and the refractive index n of the EL layer 172 (optical distance) is m times half the wavelength λ (where m is an integer of 1 or more). The distance d can be calculated using formula 1.

[0280] d = m × λ / (2 × n) (Equation 1).

[0281] According to Equation 1, the distance d of the light-emitting element 61 in the microcavity structure is determined according to the wavelength (emission color) of the emitted light. The distance d corresponds to the thickness of the EL layer 172. Therefore, the EL layer 172G may be thicker than the EL layer 172B, and the EL layer 172R may be thicker than the EL layer 172G.

[0282] More precisely, distance d is the distance from the reflective region of the conductive layer 171, which functions as a reflective electrode, to the reflective region of the conductive layer 173, which functions as a semi-transparent / semi-reflective electrode. For example, if the conductive layer 171 is a laminate of silver and a transparent conductive film called ITO, and the ITO is on the EL layer 172 side, the distance d corresponding to the emission color can be set by adjusting the thickness of the ITO. That is, even if the thicknesses of EL layers 172R, 172G, and 172B are the same, a distance d suitable for the emission color can be obtained by changing the thickness of the ITO.

[0283] However, it can be difficult to precisely determine the position of the reflective regions in the conductive layer 171 and the conductive layer 173. In this case, the light-emitting element 61 can sufficiently obtain the effect of the microcavity by assuming that any position in the conductive layer 171 and the conductive layer 173 is a reflective region.

[0284] The light-emitting element 61 is composed of, for example, a hole injection layer, a hole transport layer, an emitting layer, an electron transport layer, or an electron injection layer. Detailed examples of the configuration of the light-emitting element 61 will be described in other embodiments. In order to improve the light extraction efficiency in the microcavity structure, it is preferable to make the optical distance from the conductive layer 171, which functions as a reflective electrode, to the emitting layer an odd multiple of λ / 4. To achieve this optical distance, it is preferable to appropriately adjust the thickness of each layer constituting the light-emitting element 61.

[0285] Furthermore, when light is emitted from the conductive layer 173 side, it is preferable that the reflectance of light of the conductive layer 173 is greater than the transmittance of light. Preferably, the transmittance of light of the conductive layer 173 should be 2% to 50%, more preferably 2% to 30%, and even more preferably 2% to 10%. By reducing the transmittance of light of the conductive layer 173 (increasing the reflectance of light), the effect of the microcavity can be enhanced.

[0286] Figure 31A shows an example different from the above. Specifically, in the configuration shown in Figure 31A, the EL layer 172 extends beyond the edge of the conductive layer 171 in each of the light-emitting elements 61R, 61G, and 61B. For example, in light-emitting element 61R, the EL layer 172R extends beyond the edge of the conductive layer 171. Also, in light-emitting element 61G, the EL layer 172G extends beyond the edge of the conductive layer 171. In light-emitting element 61B, the EL layer 172B extends beyond the edge of the conductive layer 171.

[0287] Furthermore, in each of the light-emitting elements 61R, 61G, and 61B, the EL layer 172 and the protective layer 271 have overlapping regions via the insulating layer 270. In addition, an insulating layer 278 is provided on top of the protective layer 271 in the region between adjacent light-emitting elements 61.

[0288] Examples of insulating layer 278 include epoxy resin, acrylic resin, silicone resin, phenolic resin, polyimide resin, imide resin, PVC (polyvinyl chloride) resin, PVB (polyvinyl butyral) resin, or EVA (ethylene vinyl acetate) resin. Alternatively, a photoresist may be used as the insulating layer 278. The photoresist used as the insulating layer 278 may be a positive-type photoresist or a negative-type photoresist.

[0289] A common layer 174 is provided on the light-emitting element 61R, light-emitting element 61G, light-emitting element 61B, and the insulating layer 278. A conductive layer 173 is provided on the common layer 174. The common layer 174 has a region in contact with the EL layer 172R, a region in contact with the EL layer 172G, and a region in contact with the EL layer 172B. The common layer 174 is shared by the light-emitting elements 61R, 61G, and 61B.

[0290] One or more of the following can be applied as the common layer 174: a hole injection layer, a hole transport layer, a hole blocking layer, an electron blocking layer, an electron transport layer, and an electron injection layer. For example, the common layer 174 may be a carrier injection layer (a hole injection layer or an electron injection layer). The common layer 174 can also be considered a part of the EL layer 172. The common layer 174 may be provided only as needed. If the common layer 174 is provided, it is not necessary to provide any layers in the EL layer 172 that have the same function as the common layer 174.

[0291] A protective layer 273 is provided on the conductive layer 173. An insulating layer 276 is provided on the protective layer 273.

[0292] Figure 31B shows a different example from the above. Specifically, the configuration shown in Figure 31B has three light-emitting elements 61W instead of the light-emitting elements 61R, 61G, and 61B in the configuration shown in Figure 31A. Also, the configuration shown in Figure 31B has an insulating layer 276 above the three light-emitting elements 61W. Furthermore, the configuration shown in Figure 31B has colored layers 264R, 264G, and 264B above the insulating layer 276. Specifically, the colored layer 264R, which transmits red light, is positioned to overlap with the left light-emitting element 61W. The colored layer 264G, which transmits green light, is positioned to overlap with the central light-emitting element 61W. The colored layer 264B, which transmits blue light, is positioned to overlap with the right light-emitting element 61W. As a result, the display device can display a color image. Note that the configuration shown in Figure 31B is also a modified version of the configuration shown in Figure 30C.

[0293] Figure 32A is a perspective view of the display device 10. The display device 10 shown in Figure 32A includes a layer 60 superimposed on a layer 50. Layer 50 includes a plurality of pixel circuits 51 arranged in a matrix, a first drive circuit section 231, a second drive circuit section 232, and an input / output terminal section 29. Layer 60 includes a plurality of light-emitting elements 61 arranged in a matrix.

[0294] One pixel circuit 51 and one light-emitting element 61 are electrically connected to each other, functioning as one pixel 230. Therefore, the region where the multiple pixel circuits 51 in layer 50 and the multiple light-emitting elements 61 in layer 60 overlap functions as a display region 235.

[0295] Power and signals necessary for the operation of the display device 10 are supplied to the display device 10 via the input / output terminal section 29. In the display device 10 shown in Figure 32A, the transistors in the peripheral drive circuit and the transistors included in the pixels 230 can be formed in the same process.

[0296] Furthermore, as shown in Figure 32B, the display device 10 may be configured by stacking layers 40, 50, and 60. In the display device 10 shown in Figure 32B, a plurality of pixel circuits 51 arranged in a matrix are provided on layer 50, and a first drive circuit unit 231 and a second drive circuit unit 232 are provided on layer 40. In the display device 10 shown in Figure 32B, by providing the first drive circuit unit 231 and the second drive circuit unit 232 on different layers from the pixel circuits 51, the width of the frame around the display area 235 can be narrowed, thereby increasing the occupied area of ​​the display area 235.

[0297] The display device 10 shown in Figure 32B can increase its resolution by expanding the occupied area of ​​the display region 235. Alternatively, if the resolution of the display region 235 remains constant, the display device 10 shown in Figure 32B can increase the occupied area per pixel, thereby increasing the luminous brightness. Furthermore, by expanding the occupied area per pixel, the ratio of the luminous area to the occupied area of ​​one pixel (also called the "aperture ratio") can be increased. For example, the aperture ratio of a pixel can be set to 40% or more and less than 100%, preferably 50% or more and 95%, and more preferably 60% or more and 95%. In addition, by expanding the occupied area per pixel, the current density supplied to the light-emitting element 61 can be reduced. Therefore, the load on the light-emitting element 61 is reduced. As a result, the reliability of the semiconductor device 100 can be increased. Therefore, the reliability of the display device 10 including the semiconductor device 100 can be increased.

[0298] By stacking the display area 235 and peripheral drive circuits, the wiring connecting them electrically can be shortened. Therefore, wiring resistance and parasitic capacitance are reduced. As a result, the operating speed of the semiconductor device 100 can be increased. Furthermore, the power consumption of the semiconductor device 100 is reduced.

[0299] Furthermore, layer 40 may include not only peripheral drive circuits, but also a CPU 23 (Central Processing Unit), a GPU 24 (Graphics Processing Unit), and a memory circuit section 25. In this embodiment, the peripheral drive circuits, CPU 23, GPU 24, and memory circuit section 25 are collectively referred to as "functional circuits."

[0300] For example, the CPU 23 has the function of controlling the operation of the GPU 24 and the circuits provided in layer 40 according to a program stored in the memory circuit unit 25. The GPU 24 has the function of performing calculations to form image data. In addition, the GPU 24 can perform many matrix operations (multiply-accumulate operations) in parallel, so it can perform calculations using neural networks at high speed, for example. The GPU 24 has the function of correcting image data using correction data stored in the memory circuit unit 25, for example. For example, the GPU 24 has the function of generating image data in which one or more of the following have been corrected: brightness, hue, and contrast.

[0301] The display device 10 may use the GPU 24 to upconvert or downconvert image data. The display device 10 may also be provided with a super-resolution circuit in layer 40. The super-resolution circuit has the function of determining the potential of any pixel in the display area 235 by performing a sum-of-products operation on the potentials and weights of pixels arranged around that pixel. The super-resolution circuit has the function of upconverting image data with a resolution lower than that of the display area 235. The super-resolution circuit also has the function of downconverting image data with a resolution higher than that of the display area 235.

[0302] The display device 10 can reduce the load on the GPU 24 by incorporating a super-resolution circuit. For example, the load on the GPU 24 can be reduced by processing up to 2K resolution (or 4K resolution) with the GPU 24 and then upconverting to 4K resolution (or 8K resolution) using the super-resolution circuit. Downconversion can be performed in the same manner.

[0303] The functional circuits of layer 40 do not necessarily have to include all of these configurations, and may include other configurations. For example, it may include one or more of the following: a potential generation circuit that generates multiple different potentials, and a power management circuit that controls the supply or stop of power for each circuit of the display device 10.

[0304] Power supply or deactivation may be performed for each circuit constituting the CPU 23. For example, the power supply to a circuit that is determined not to be used for a while can be deactivated, and the power supply can be resumed when needed, thereby reducing the power consumption of the CPU 23. The data required when power supply is resumed can be stored, for example, in a memory circuit or memory circuit unit 25 within the CPU 23 before the circuit is deactivated. By storing the data required when the circuit is restored, for example, in a memory circuit or memory circuit unit 25 within the CPU 23, a high-speed recovery of the deactivated circuit can be achieved. In addition, the CPU 23 may stop circuit operation by stopping the supply of a clock signal.

[0305] Furthermore, the functional circuit may include one or more of the following: a DSP circuit, a sensor circuit, a communication circuit, and an FPGA (Field Programmable Gate Array).

[0306] Some of the transistors constituting the functional circuit of layer 40 may be provided in layer 50. Similarly, some of the transistors constituting the pixel circuit 51 of layer 50 may be provided in layer 40. Therefore, the functional circuit may include Si transistors and OS transistors. Furthermore, the pixel circuit 51 may also include Si transistors and OS transistors.

[0307] Figure 33 shows a partial cross-sectional configuration example of the display device 10 shown in Figure 32A. The display device 10 shown in Figure 33 comprises a layer 50 including a substrate 301, a capacitor 246, and a transistor 310, and a layer 60 including light-emitting elements 61R, 61G, and 61B. The layer 60 is provided on the insulating layer 363 of the layer 50.

[0308] The transistor 310 is a transistor having a channel-forming region in the substrate 301. A semiconductor substrate, such as a single-crystal silicon substrate, can be used as the substrate 301. The transistor 310 comprises a portion of the substrate 301, a conductive layer 311, a low-resistance region 312, an insulating layer 313, and an insulating layer 314. The conductive layer 311 functions as a gate electrode. The insulating layer 313 is located between the substrate 301 and the conductive layer 311 and functions as a gate insulating layer. The low-resistance region 312 is a region of the substrate 301 doped with impurities and functions as either a source or a drain. The insulating layer 314 covers the side surface of the conductive layer 311 and functions as an insulating layer.

[0309] The element isolation layer 315 is provided between two adjacent transistors 310 so as to be embedded in the substrate 301.

[0310] An insulating layer 261 is provided covering the transistor 310. A capacitor 246 is provided on the insulating layer 261.

[0311] Capacitor 246 comprises a conductive layer 241, a conductive layer 245, and an insulating layer 243 located between them. Conductive layer 241 functions as one electrode of capacitor 246. Conductive layer 245 functions as the other electrode of capacitor 246. Insulating layer 243 functions as the dielectric of capacitor 246.

[0312] The conductive layer 241 is provided on the insulating layer 261 and embedded in the insulating layer 254. The conductive layer 241 is electrically connected to either the source or drain of the transistor 310 by a plug 266 embedded in the insulating layer 261. The insulating layer 243 is provided covering the conductive layer 241. The conductive layer 245 is provided in the region overlapping with the conductive layer 241 via the insulating layer 243.

[0313] An insulating layer 255 is provided covering the capacitance 246. An insulating layer 363 is provided on the insulating layer 255. Light-emitting elements 61R, 61G, and 61B are provided on the insulating layer 363. A protective layer 415 is provided on the light-emitting elements 61R, 61G, and 61B. A substrate 420 is provided on the upper surface of the protective layer 415 via a resin layer 419.

[0314] The pixel electrodes of the light-emitting element are electrically connected to either the source or drain of the transistor 310 by plugs 256 embedded in insulating layer 243, insulating layer 255, and insulating layer 363, a conductive layer 241 embedded in insulating layer 254, and plugs 266 embedded in insulating layer 261.

[0315] Figure 34 shows a modified example of the cross-sectional configuration shown in Figure 33. The main difference between the cross-sectional configuration example of the display device 10 shown in Figure 34 and the example in Figure 33 is the inclusion of transistor 320 instead of transistor 310. Note that explanations of parts similar to those in Figure 33 may be omitted.

[0316] Transistor 320 is a transistor in which a metal oxide (also called an oxide semiconductor) is applied to the semiconductor layer where the channel is formed.

[0317] The transistor 320 comprises a semiconductor layer 321, an insulating layer 323, a conductive layer 324, a pair of conductive layers 325, an insulating layer 326, and a conductive layer 327.

[0318] An insulating substrate or a semiconductor substrate can be used as the substrate 331.

[0319] An insulating layer 332 is provided on the substrate 331. The insulating layer 332 functions as a barrier layer that prevents impurities such as water or hydrogen from diffusing from the substrate 331 to the transistor 320, and prevents oxygen from detaching from the semiconductor layer 321 to the insulating layer 332. As the insulating layer 332, a film that is less susceptible to hydrogen or oxygen diffusion compared to a silicon oxide film can be used. For example, the insulating layer 332 can be an aluminum oxide film, a hafnium oxide film, or a silicon nitride film.

[0320] A conductive layer 327 is provided on an insulating layer 332. An insulating layer 326 is provided covering the conductive layer 327. The conductive layer 327 functions as the first gate electrode of the transistor 320. A portion of the insulating layer 326 functions as the first gate insulating layer. It is preferable to use an oxide insulating film, such as a silicon oxide film, for at least the portion of the insulating layer 326 that is in contact with the semiconductor layer 321. It is preferable that the upper surface of the insulating layer 326 is flattened.

[0321] The semiconductor layer 321 is provided on the insulating layer 326. Preferably, the semiconductor layer 321 comprises a metal oxide (also called an oxide semiconductor) film having semiconductor properties. Details of materials suitably used for the semiconductor layer 321 will be described later.

[0322] A pair of conductive layers 325 are provided in contact with the semiconductor layer 321 and function as source and drain electrodes.

[0323] The insulating layer 328 is provided covering, for example, the top and side surfaces of a pair of conductive layers 325, and the side surfaces of the semiconductor layer 321. The insulating layer 264 is provided on the insulating layer 328. The insulating layer 328 functions as a barrier layer that prevents impurities such as water or hydrogen from diffusing from, for example, the insulating layer 264 to the semiconductor layer 321, and prevents oxygen from being released from the semiconductor layer 321. An insulating film similar to that of the insulating layer 332 can be used as the insulating layer 328.

[0324] An opening is provided in the insulating layer 328 and the insulating layer 264 that reaches the semiconductor layer 321. The insulating layer 323 and the conductive layer 324, which are in contact with the insulating layer 264, the insulating layer 328, the side surface of the conductive layer 325, and the upper surface of the semiconductor layer 321, are embedded inside the opening. The conductive layer 324 functions as a second gate electrode. The insulating layer 323 functions as a second gate insulating layer.

[0325] The upper surfaces of the conductive layer 324, the insulating layer 323, and the insulating layer 264 are flattened so that their heights are approximately the same. In addition, insulating layers 329 and 265 are provided covering these surfaces.

[0326] Insulating layers 264 and 265 function as interlayer insulating layers. Insulating layer 329 functions as a barrier layer that prevents impurities, such as water or hydrogen, from diffusing from, for example, insulating layer 265 to transistor 320. An insulating film similar to that used for insulating layers 328 and 332 can be used as insulating layer 329.

[0327] A plug 274, which is electrically connected to one of the pair of conductive layers 325, is provided so as to be embedded in the insulating layers 265, 329, and 264. Here, it is preferable that the plug 274 comprises a conductive layer 274a that covers the sides of the openings of the insulating layers 265, 329, 264, and 328, as well as a portion of the upper surface of the conductive layer 325, and a conductive layer 274b that is in contact with the upper surface of the conductive layer 274a. In this case, it is preferable to use a conductive material that does not easily allow hydrogen and oxygen to diffuse as the conductive layer 274a.

[0328] Figure 35 shows an example of a partial cross-sectional configuration of the display device 10 shown in Figure 32B. The display device 10 shown in Figure 35 has a stacked configuration in which a transistor 310A with a channel formed on a substrate 301A provided on layer 40 and a transistor 310B with a channel formed on a substrate 301B provided on layer 50 are stacked. The same material as substrate 301 can be used for substrate 301A.

[0329] The display device 10 shown in Figure 35 has a structure in which a layer 60 on which a light-emitting element 61 is provided, a layer 50 on which a substrate 301B, a transistor 310B, and a capacitor 246 are provided, and a layer 40 on which a substrate 301A and a transistor 310A are provided are bonded together.

[0330] A plug 343 that penetrates the substrate 301B is provided on the substrate 301B. The plug 343 functions as a through-silicon via (TSV). The plug 343 is electrically connected to a conductive layer 342 provided on the back surface of the substrate 301B (the surface opposite to the substrate 420 side). A conductive layer 341 is provided on the insulating layer 261 of the substrate 301A.

[0331] The conductive layer 341 and the conductive layer 342 are joined together, thereby electrically connecting layer 40 and layer 50.

[0332] It is preferable to use the same conductive material for conductive layer 341 and conductive layer 342. For example, a metal film containing an element selected from Al, Cr, Cu, Ta, Sn, Zn, Au, Ag, Pt, Ti, Mo, and W, or a metal nitride film (titanium nitride film, molybdenum nitride film, or tungsten nitride film) composed of the above elements can be used. In particular, it is preferable to use copper for conductive layer 341 and conductive layer 342. This allows the application of Cu-Cu (copper-copper) direct bonding technology (a technology that achieves electrical conductivity by connecting Cu (copper) pads) as the bonding between conductive layer 341 and conductive layer 342. The conductive layer 341 and conductive layer 342 may be bonded via bumps.

[0333] Figure 36 is a modified example of the cross-sectional configuration shown in Figure 35. The cross-sectional configuration example of the display device 10 shown in Figure 36 has a configuration in which a transistor 310A with a channel formed on a substrate 301A and a transistor 320 containing a metal oxide in the semiconductor layer where the channel is formed are stacked. Note that explanations of parts similar to those in Figures 33 to 35 may be omitted.

[0334] The layer 50 shown in Figure 36 has the same configuration as the layer 50 shown in Figure 34, but without the substrate 331. In the layer 40 shown in Figure 36, an insulating layer 261 is provided covering the transistor 310A. A conductive layer 251 is provided on the insulating layer 261. An insulating layer 262 is provided covering the conductive layer 251. A conductive layer 252 is provided on the insulating layer 262. The conductive layers 251 and 252 each function as wiring. Insulating layers 263 and 332 are provided covering the conductive layer 252. The transistor 320 is provided on the insulating layer 332. An insulating layer 265 is provided covering the transistor 320. A capacitor 246 is provided on the insulating layer 265. The capacitor 246 and the transistor 320 are electrically connected by a plug 274. Layer 50 is provided on top of the insulating layer 263 of layer 40.

[0335] Transistor 320 can be used as a transistor constituting the pixel circuit 51. Transistor 310 can be used as a transistor constituting the pixel circuit 51 or as a transistor constituting a peripheral drive circuit. Transistors 310 and 320 can be used as transistors constituting a functional circuit, such as an arithmetic circuit or a memory circuit.

[0336] In the display device 10 shown in Figure 36, this configuration allows for the formation of not only the pixel circuit 51 but also peripheral drive circuits, etc., directly beneath the layer 60 containing the light-emitting element 61. Therefore, it is possible to miniaturize the display device compared to the case where the drive circuits are located around the display area.

[0337] The configuration shown in this embodiment can be used in appropriate combination with the configurations shown in other embodiments and examples.

[0338] (Embodiment 4) This embodiment describes a transistor that can be used in a semiconductor device according to one aspect of the present invention.

[0339] <Example of transistor configuration> Figures 37A, 37B, and 37C are a top view and a cross-sectional view of a transistor 500 that can be used in a semiconductor device according to one aspect of the present invention. The transistor 500 can be applied to a semiconductor device according to one aspect of the present invention.

[0340] Figure 37A is a top view of transistor 500. Figures 37B and 37C are cross-sectional views of transistor 500. Here, Figure 37B is a cross-sectional view of the area indicated by the dashed line A1-A2 in Figure 37A. This is also a cross-sectional view of transistor 500 in the channel length direction. Figure 37C is a cross-sectional view of the area indicated by the dashed line A3-A4 in Figure 37A. This is also a cross-sectional view of transistor 500 in the channel width direction. Note that some elements have been omitted from the top view of Figure 37A for clarity.

[0341] As shown in Figure 37, the transistor 500 has a metal oxide 531a disposed on a substrate (not shown). It also has a metal oxide 531b disposed on top of the metal oxide 531a. It also has conductors 542a and 542b disposed spaced apart from each other on top of the metal oxide 531b. It also has an insulator 580 disposed on top of the conductors 542a and 542b, with an opening formed between the conductors 542a and 542b. It also has a conductor 560 disposed within the opening. It also has an insulator 550 disposed between the metal oxide 531b, conductor 542a, conductor 542b, insulator 580, and conductor 560. It also has a metal oxide 531c disposed between the metal oxide 531b, conductor 542a, conductor 542b, insulator 580, and insulator 550. Here, as shown in Figures 37B and 37C, it is preferable that the upper surface of the conductor 560 substantially coincides with the upper surfaces of the insulator 550, insulator 554, metal oxide 531c, and insulator 580. In the following, metal oxide 531a, metal oxide 531b, and metal oxide 531c may be collectively referred to as metal oxide 531. Also, conductors 542a and conductor 542b may be collectively referred to as conductor 542.

[0342] In the transistor 500 shown in Figure 37, the sides of the conductors 542a and 542b facing the conductor 560 have a generally vertical shape. However, the transistor 500 is not limited to this. In the transistor 500, the angle between the side and bottom surfaces of the conductors 542a and 542b may be 10° or more and 80° or less, preferably 30° or more and 60° or less. Also, the opposing sides of the conductors 542a and 542b may have multiple surfaces.

[0343] As shown in Figure 37, in the transistor 500, it is preferable that an insulator 554 is placed between the insulator 524, metal oxide 531a, metal oxide 531b, conductor 542a, conductor 542b, and metal oxide 531c and the insulator 580. Here, as shown in Figures 37B and 37C, it is preferable that the insulator 554 is in contact with the side surface of the metal oxide 531c, the top and side surfaces of the conductor 542a, the top and side surfaces of the conductor 542b, the side surfaces of the metal oxide 531a and metal oxide 531b, and the top surface of the insulator 524.

[0344] In the transistor 500 shown in Figure 37, the metal oxide 531 is configured as a stack of three layers of metal oxide 531a, metal oxide 531b, and metal oxide 531c in the region where the channel is formed (hereinafter also referred to as the channel formation region) and its vicinity. However, the present invention is not limited to this configuration. For example, the metal oxide 531 may be configured as a two-layer structure of metal oxide 531b and metal oxide 531c, or as a stacked structure of four or more layers. Also, in the transistor 500 shown in Figure 37, the conductor 560 is configured as a two-layer stacked structure. However, the present invention is not limited to this configuration. For example, the conductor 560 may be a single-layer structure or a stacked structure of three or more layers. Furthermore, for example, in the metal oxide 531, each of the metal oxide 531a, metal oxide 531b, and metal oxide 531c may have a stacked structure of two or more layers.

[0345] For example, if the metal oxide 531c has a layered structure consisting of a first metal oxide and a second metal oxide provided on the first metal oxide, it is preferable that the first metal oxide has the same composition as metal oxide 531b and the second metal oxide has the same composition as metal oxide 531a.

[0346] Here, the conductor 560 functions as the gate electrode of the transistor. Conductors 542a and 542b function as the source electrode or drain electrode of the transistor, respectively. As described above, the conductor 560 is formed to be embedded in the opening of the insulator 580 and in the region sandwiched between conductors 542a and 542b. Here, the arrangement of conductors 560, 542a, and 542b is selected in a self-aligned manner with respect to the opening of the insulator 580. In other words, one aspect of the present invention allows the gate electrode of the transistor 500 to be positioned in a self-aligned manner between the source electrode and the drain electrode. Therefore, the conductor 560 can be formed without providing a margin for alignment. As a result, the occupied area of ​​the transistor 500 can be reduced. This allows for a higher resolution display device. It also allows for a narrower bezel display device.

[0347] As shown in Figure 37, it is preferable that the conductor 560 has a conductor 560a provided inside the insulator 550 and a conductor 560b provided so as to be embedded inside the conductor 560a.

[0348] The transistor 500 preferably includes an insulator 514 disposed on a substrate (not shown), an insulator 516 disposed on top of the insulator 514, a conductor 505 disposed so as to be embedded in the insulator 516, an insulator 522 disposed on top of the insulator 516 and the conductor 505, and an insulator 524 disposed on top of the insulator 522. Furthermore, it is preferable that a metal oxide 531a is disposed on top of the insulator 524.

[0349] It is preferable that insulators 574 and 581, which function as interlayer films, are placed on top of the transistor 500. Here, it is preferable that insulator 574 is placed in contact with the upper surfaces of conductor 560, insulator 550, insulator 554, metal oxide 531c, and insulator 580.

[0350] It is preferable that insulators 522, 554, and 574 have a function to suppress the diffusion of hydrogen (for example, at least one such as hydrogen atoms and hydrogen molecules). For example, it is preferable that insulators 522, 554, and 574 have lower hydrogen permeability than insulators 524, 550, and 580. It is also preferable that insulators 522 and 554 have a function to suppress the diffusion of oxygen (for example, at least one such as oxygen atoms and oxygen molecules). For example, it is preferable that insulators 522 and 554 have lower oxygen permeability than insulators 524, 550, and 580.

[0351] Here, insulator 524, metal oxide 531, and insulator 550 are separated from insulators 580 and 581 by insulators 554 and 574. Therefore, insulators 554 and 574 can prevent impurities such as hydrogen and excess oxygen contained in insulators 580 and 581 from mixing into insulators 524, metal oxide 531, and insulator 550.

[0352] It is preferable that a conductor 545 (conductor 545a and conductor 545b) is provided that is electrically connected to the transistor 500 and functions as a plug. In addition, an insulator 541 (insulator 541a and insulator 541b) is provided in contact with the side surface of the conductor 545 that functions as a plug. That is, the insulator 541 is provided in contact with the inner wall of the opening of the insulator 554, insulator 580, insulator 574, and insulator 581. Alternatively, the first conductor of the conductor 545 may be provided in contact with the side surface of the insulator 541, and the second conductor of the conductor 545 may be provided inside the first conductor of the conductor 545. Here, the height of the upper surface of the conductor 545 and the height of the upper surface of the insulator 581 can be made to be approximately the same. In the transistor 500 shown in Figure 37, the first conductor and the second conductor of the conductor 545 are stacked, but the present invention is not limited to this. For example, the conductor 545 may be provided as a single layer or as a stacked structure of three or more layers. When a structure has a stacked structure, an ordinal number may be assigned to distinguish it according to the order of formation.

[0353] In transistor 500, it is preferable to use a metal oxide that functions as an oxide semiconductor (hereinafter also referred to as an oxide semiconductor) for the metal oxide 531 (metal oxide 531a, metal oxide 531b, and metal oxide 531c) that includes the channel formation region. For example, it is preferable to use a metal oxide with a band gap of 2 eV or more, preferably 2.5 eV or more, as the metal oxide that forms the channel formation region of metal oxide 531.

[0354] The above metal oxide preferably contains at least indium (In) or zinc (Zn). In particular, it is preferable that it contains indium (In) and zinc (Zn). In addition, it is preferable that it contains element M. As element M, one or more of aluminum (Al), gallium (Ga), yttrium (Y), tin (Sn), boron (B), titanium (Ti), iron (Fe), nickel (Ni), germanium (Ge), zirconium (Zr), molybdenum (Mo), lanthanum (La), cerium (Ce), neodymium (Nd), hafnium (Hf), tantalum (Ta), tungsten (W), magnesium (Mg), and cobalt (Co) can be used. In particular, it is preferable that element M is one or more of aluminum (Al), gallium (Ga), yttrium (Y), and tin (Sn). Furthermore, it is even more preferable that element M contains either Ga or Sn, or both.

[0355] Furthermore, as shown in Figure 37B, the thickness of the metal oxide 531b in the region that does not overlap with the conductor 542 may be thinner than the thickness of the region that overlaps with the conductor 542. This is because, when forming the conductors 542a and 542b, a portion of the region on the upper surface of the metal oxide 531b that does not overlap with the conductors 542a and 542b is removed. Here, when a conductive film that will become the conductor 542 is deposited on the upper surface of the metal oxide 531b, a region with low resistance may be formed near the interface with the conductive film. Therefore, by removing the region with low resistance located between the conductors 542a and 542b on the upper surface of the metal oxide 531b, it is possible to prevent the formation of a channel in that region.

[0356] One aspect of the present invention provides a display device with high resolution by having a small-sized transistor. Alternatively, it provides a display device with high brightness by having a transistor with a large on-current. Alternatively, it provides a display device with fast operation by having a transistor with fast operation. Alternatively, it provides a display device with high reliability by having a transistor with stable electrical characteristics. Alternatively, it provides a display device with low power consumption by having a transistor with a small off-current.

[0357] A detailed configuration of the transistor 500, which can be used in a display device according to one aspect of the present invention, will be described.

[0358] The conductor 505 is arranged to have an overlapping region with the metal oxide 531 and the conductor 560. Furthermore, it is preferable that the conductor 505 is embedded in the insulator 516.

[0359] The conductor 505 comprises conductor 505a, conductor 505b, and conductor 505c. Conductor 505a is provided in contact with the bottom surface and side wall of an opening provided in the insulator 516. Conductor 505b is provided so as to be embedded in a recess formed in conductor 505a. Here, the upper surface of conductor 505b is lower than the upper surface of conductor 505a and the upper surface of the insulator 516. Conductor 505c is provided in contact with the upper surface of conductor 505b and the side surface of conductor 505a. Here, the height of the upper surface of conductor 505c is approximately equal to the height of the upper surface of conductor 505a and the upper surface of the insulator 516. In other words, conductor 505b is enclosed by conductors 505a and conductor 505c.

[0360] It is preferable that the conductors 505a and 505c use conductive materials that have the function of suppressing the diffusion of impurities such as hydrogen atoms, hydrogen molecules, water molecules, nitrogen atoms, nitrogen molecules, nitrogen oxide molecules (e.g., N2O, NO, or NO2), or copper atoms. Alternatively, it is preferable to use conductive materials that have the function of suppressing the diffusion of oxygen (e.g., at least one such as oxygen atoms and oxygen molecules).

[0361] By using conductive materials that have the function of reducing hydrogen diffusion for conductors 505a and 505c, it is possible to suppress the diffusion of impurities such as hydrogen contained in conductor 505b into the metal oxide 531 via, for example, an insulator 524. Furthermore, by using conductive materials that have the function of suppressing oxygen diffusion for conductors 505a and 505c, it is possible to suppress the oxidation of conductor 505b and the resulting decrease in conductivity. As conductive materials that have the function of suppressing oxygen diffusion, it is preferable to use, for example, titanium, titanium nitride, tantalum, tantalum nitride, ruthenium, or ruthenium oxide. Therefore, conductor 505a may be made of the above conductive material in a single layer or a laminate. For example, titanium nitride may be used for conductor 505a.

[0362] Furthermore, it is preferable to use a conductive material whose main component is tungsten, copper, or aluminum for the conductor 505b. For example, tungsten may be used for the conductor 505b.

[0363] Here, the conductor 560 may function as the first gate (also called the top gate) electrode. Also, the conductor 505 may function as the second gate (also called the bottom gate) electrode. In that case, the Vth of transistor 500 can be controlled by changing the potential applied to conductor 505 independently of the potential applied to conductor 560. In particular, by applying a negative potential to conductor 505, it is possible to make the Vth of transistor 500 greater than 0V and reduce the off-current. Therefore, applying a negative potential to conductor 505 reduces the drain current when the potential applied to conductor 560 is 0V compared to not applying a negative potential.

[0364] The conductor 505 should be larger than the channel-forming region in the metal oxide 531. In particular, as shown in Figure 37C, it is preferable that the conductor 505 extends to the region outside the end that intersects with the channel width direction of the metal oxide 531. That is, it is preferable that the conductor 505 and the conductor 560 are superimposed on the outside of the side surface in the channel width direction of the metal oxide 531, with an insulator in between.

[0365] In transistor 500, having the above configuration, the channel formation region of the metal oxide 531 can be electrically surrounded by the electric field of the conductor 560 which functions as the first gate electrode and the electric field of the conductor 505 which functions as the second gate electrode.

[0366] As shown in Figure 37C, the conductor 505 extends and functions as wiring. However, the present invention is not limited to this, and in one embodiment, a conductor that functions as wiring may be provided below the conductor 505.

[0367] The insulator 514 preferably functions as a barrier insulating film that suppresses the ingress of impurities such as water or hydrogen from the substrate side into the transistor 500. Therefore, it is preferable to use an insulating material for the insulator 514 that has the function of suppressing the diffusion of impurities such as hydrogen atoms, hydrogen molecules, water molecules, nitrogen atoms, nitrogen molecules, nitrogen oxide molecules (e.g., N2O, NO, or NO2), or copper atoms (the above impurities are less permeable). Alternatively, it is preferable to use an insulating material that has the function of suppressing the diffusion of oxygen (e.g., at least one of oxygen atoms and oxygen molecules) (the above oxygen is less permeable).

[0368] For example, it is preferable to use aluminum oxide or silicon nitride as the insulator 514. This allows the insulator 514 to suppress the diffusion of impurities such as water or hydrogen from the substrate side to the transistor 500 side. Alternatively, the insulator 514 can suppress the diffusion of oxygen contained in, for example, the insulator 524, to the substrate side beyond the insulator 514.

[0369] The insulators 516, 580, and 581, which function as interlayer films, preferably have a lower dielectric constant than insulator 514. In one aspect of the present invention, by using a material with a low dielectric constant as the interlayer film, parasitic capacitance occurring between wiring can be reduced. For example, as insulators 516, 580, and 581, appropriate materials such as silicon oxide, silicon oxide nitride, silicon nitride, silicon oxide with added fluorine, silicon oxide with added carbon, silicon oxide with added carbon and nitrogen, or silicon oxide with vacancies may be used.

[0370] Insulators 522 and 524 function as gate insulators.

[0371] Here, the insulator 524 in contact with the metal oxide 531 preferably desorbs oxygen upon heating. In this specification, the oxygen desorbed upon heating may be referred to as excess oxygen. For example, the insulator 524 may be appropriately silicon oxide, silicon oxynitride, or the like. In the transistor 500, by providing the insulator 524 containing oxygen in contact with the metal oxide 531, the oxygen deficiency in the metal oxide 531 can be reduced, and the reliability of the transistor 500 can be improved.

[0372] Specifically, as the insulator 524, it is preferable to use an oxide material in which some oxygen desorbs upon heating. The oxide that desorbs oxygen upon heating is an oxide film in which the desorption amount of oxygen converted to oxygen atoms is 1.0×10 18 atoms / cm 3 or more, preferably 1.0×10 19 atoms / cm 3 or more, more preferably 2.0×10 19 atoms / cm 3 or more, or 3.0×10 20 atoms / cm 3 or more. The surface temperature of the film during the above TDS analysis is preferably in the range of 100°C or more and 700°C or less, or 100°C or more and 400°C or less.

[0373] As shown in FIG. 37C, in the insulator 524, the film thickness of the region that does not overlap with the insulator 554 and does not overlap with the metal oxide 531b may be thinner than the film thickness of other regions. In the insulator 524, the film thickness of the region that does not overlap with the insulator 554 and does not overlap with the metal oxide 531b is preferably a film thickness that allows sufficient diffusion of the above oxygen.

[0374] The insulator 522 preferably functions as a barrier insulating film that suppresses the ingress of impurities such as water or hydrogen into the transistor 500 from the substrate side, similar to, for example, the insulator 514. For example, the insulator 522 preferably has lower hydrogen permeability than the insulator 524. In one aspect of the present invention, by surrounding, for example, the insulator 524, the metal oxide 531, and the insulator 550 with the insulator 522, the insulator 554, and the insulator 574, it is possible to suppress the ingress of impurities such as water or hydrogen into the transistor 500 from the outside.

[0375] Furthermore, it is preferable that the insulator 522 has a function to suppress the diffusion of oxygen (for example, at least one such as oxygen atoms and oxygen molecules) (i.e., it is difficult for the above-mentioned oxygen to permeate it). For example, it is preferable that the insulator 522 has lower oxygen permeability than the insulator 524. By having the function of suppressing the diffusion of oxygen and impurities, the diffusion of oxygen contained in the metal oxide 531 to the substrate side can be reduced. In addition, it is possible to suppress the reaction of the conductor 505 with the oxygen contained in the insulator 524 and the metal oxide 531.

[0376] The insulator 522 may be an insulator containing an oxide of either or both aluminum and hafnium, which are insulating materials. For example, it is preferable to use aluminum oxide, hafnium oxide, or an oxide containing aluminum and hafnium (hafnium aluminate) as the insulator containing either or both aluminum and hafnium oxides. When the insulator 522 is formed using such a material, the insulator 522 functions as a layer that suppresses the release of oxygen from the metal oxide 531 and the incorporation of impurities such as hydrogen from the periphery of the transistor 500 into the metal oxide 531.

[0377] Alternatively, the insulator 522 may have, for example, aluminum oxide, bismuth oxide, germanium oxide, niobium oxide, silicon oxide, titanium oxide, tungsten oxide, yttrium oxide, or zirconium oxide added to these insulators. Alternatively, these insulators may be nitrided. Alternatively, silicon oxide, silicon oxide nitride, or silicon nitride may be laminated onto the above insulators.

[0378] The insulator 522 may be a single-layer or multi-layer insulator containing so-called high-k materials such as aluminum oxide, hafnium oxide, tantalum oxide, zirconium oxide, lead zirconate titanate (PZT), strontium titanate (SrTiO3), or (Ba,Sr)TiO3 (BST). As transistors become smaller and more integrated, thinning of the gate insulator can lead to problems such as leakage current. In transistor 500, using a high-k material as the insulator that functions as the gate insulator makes it possible to reduce the gate potential during transistor operation while maintaining the physical film thickness.

[0379] Furthermore, the insulators 522 and 524 may have a laminated structure of two or more layers. In that case, the laminated structure is not limited to being made of the same material, but may be made of different materials. For example, an insulator similar to the insulator 524 may be provided below the insulator 522.

[0380] The metal oxide 531 comprises a metal oxide 531a, a metal oxide 531b on the metal oxide 531a, and a metal oxide 531c on the metal oxide 531b. In the metal oxide 531, having the metal oxide 531a below the metal oxide 531b suppresses the diffusion of impurities from structures formed below the metal oxide 531a to the metal oxide 531b. Furthermore, in the metal oxide 531, having the metal oxide 531c on the metal oxide 531b suppresses the diffusion of impurities from structures formed above the metal oxide 531c to the metal oxide 531b.

[0381] Furthermore, it is preferable that the metal oxide 531 has a layered structure of multiple oxide layers with different atomic ratios of each metal atom. For example, if the metal oxide 531 contains at least indium (In) and element M, it is preferable that the ratio of the number of atoms of element M contained in metal oxide 531a to the total number of atoms of all elements constituting metal oxide 531a is higher than the ratio of the number of atoms of element M contained in metal oxide 531b to the total number of atoms of all elements constituting metal oxide 531b. It is also preferable that the atomic ratio of element M contained in metal oxide 531a to In is higher than the atomic ratio of element M contained in metal oxide 531b to In. Here, metal oxide 531c can be any metal oxide that can be used for metal oxide 531a or metal oxide 531b.

[0382] It is preferable that the energy at the lower end of the conduction band of metal oxide 531a and metal oxide 531c is higher than the energy at the lower end of the conduction band of metal oxide 531b. In other words, it is preferable that the electron affinity of metal oxide 531a and metal oxide 531c is smaller than the electron affinity of metal oxide 531b. In this case, it is preferable that metal oxide 531c is a metal oxide that can be used for metal oxide 531a. Specifically, it is preferable that the ratio of the number of atoms of element M contained in metal oxide 531c to the total number of atoms of all elements constituting metal oxide 531c is higher than the ratio of the number of atoms of element M contained in metal oxide 531b to the total number of atoms of all elements constituting metal oxide 531b. It is also preferable that the atomic ratio of element M contained in metal oxide 531c to In is higher than the atomic ratio of element M contained in metal oxide 531b to In.

[0383] Here, at the junctions of metal oxide 531a, metal oxide 531b, and metal oxide 531c, the energy levels at the lower end of the conduction band change smoothly. In other words, the energy levels at the lower end of the conduction band at the junctions of metal oxide 531a, metal oxide 531b, and metal oxide 531c can be said to change continuously or be continuously joined. To achieve this, it is desirable to lower the defect level density of the mixed layer formed at the interface between metal oxide 531a and metal oxide 531b, and at the interface between metal oxide 531b and metal oxide 531c.

[0384] Specifically, a mixed layer with a low defect level density can be formed by having metal oxide 531a and metal oxide 531b, and metal oxide 531b and metal oxide 531c, have a common element other than oxygen (which is the main component). For example, if metal oxide 531b is In-Ga-Zn oxide, then metal oxide 531a and metal oxide 531c may be, for example, In-Ga-Zn oxide, Ga-Zn oxide, or gallium oxide. Furthermore, metal oxide 531c may be in a layered structure. For example, a layered structure of In-Ga-Zn oxide and Ga-Zn oxide on the In-Ga-Zn oxide, or a layered structure of In-Ga-Zn oxide and gallium oxide on the In-Ga-Zn oxide can be used. In other words, a layered structure of In-Ga-Zn oxide and an oxide that does not contain In may be used as metal oxide 531c.

[0385] Specifically, for metal oxide 531a, a metal oxide with an atomic ratio of In:Ga:Zn = 1:3:4 or 1:1:0.5 may be used. For metal oxide 531b, a metal oxide with an atomic ratio of In:Ga:Zn = 4:2:3 or 3:1:2 may be used. For metal oxide 531c, a metal oxide with an atomic ratio of In:Ga:Zn = 1:3:4, In:Ga:Zn = 4:2:3, Ga:Zn = 2:1, or Ga:Zn = 2:5 may be used. Furthermore, specific examples of layered structures for metal oxide 531c include, for example, a layered structure of In:Ga:Zn=4:2:3 [atomic ratio] and Ga:Zn=2:1 [atomic ratio], a layered structure of In:Ga:Zn=4:2:3 [atomic ratio] and Ga:Zn=2:5 [atomic ratio], or a layered structure of In:Ga:Zn=4:2:3 [atomic ratio] and gallium oxide.

[0386] In this case, the main carrier pathway in metal oxide 531 is metal oxide 531b. By configuring metal oxide 531a and metal oxide 531c as described above, the defect level density at the interface between metal oxide 531a and metal oxide 531b, and at the interface between metal oxide 531b and metal oxide 531c, can be reduced. Therefore, in metal oxide 531, the influence of interface scattering on carrier conduction is reduced, and the transistor 500 can obtain a high on-current and high frequency characteristics. Furthermore, when metal oxide 531c is in a stacked structure, in addition to the effect of reducing the defect level density at the interface between metal oxide 531b and metal oxide 531c as described above, the diffusion of constituent elements of metal oxide 531c to the insulator 550 can be suppressed. More specifically, when an oxide that does not contain In is stacked on top of metal oxide 531c, the metal oxide 531c can suppress the diffusion of In to the insulator 550. The insulator 550 functions as a gate insulator. Therefore, if In diffuses into the insulator 550, the transistor 500 will exhibit poor characteristics. Accordingly, one aspect of the present invention makes it possible to provide a highly reliable display device by using a laminated structure for the metal oxide 531c.

[0387] A conductor 542 (conductor 542a and conductor 542b) that functions as a source electrode and a drain electrode is provided on a metal oxide 531b. It is preferable to use a metal element selected from, for example, aluminum, chromium, copper, silver, gold, platinum, tantalum, nickel, titanium, molybdenum, tungsten, hafnium, vanadium, niobium, manganese, magnesium, zirconium, beryllium, indium, ruthenium, iridium, strontium, and lanthanum, an alloy composed of the above-mentioned metal elements, or an alloy combining the above-mentioned metal elements. For example, it is preferable to use tantalum nitride, titanium nitride, tungsten, nitrides containing titanium and aluminum, nitrides containing tantalum and aluminum, ruthenium oxide, ruthenium nitride, an oxide containing strontium and ruthenium, or an oxide containing lanthanum and nickel. Furthermore, tantalum nitride, titanium nitride, nitrides containing titanium and aluminum, nitrides containing tantalum and aluminum, ruthenium oxide, ruthenium nitride, oxides containing strontium and ruthenium, or oxides containing lanthanum and nickel are preferred because they are conductive materials that are resistant to oxidation or maintain conductivity even when absorbing oxygen.

[0388] By providing the conductor 542 in contact with the metal oxide 531, the oxygen concentration in the vicinity of the conductor 542 on the metal oxide 531 may be reduced. Furthermore, a metal compound layer containing the metal in the conductor 542 and components of the metal oxide 531 may be formed in the vicinity of the conductor 542 on the metal oxide 531. In such cases, the carrier concentration increases in the region of the metal oxide 531 near the conductor 542, resulting in a low-resistance region.

[0389] Here, the region between the conductor 542a and the conductor 542b is formed superimposed on the opening of the insulator 580. This allows the conductor 560 to be self-aligned between the conductor 542a and the conductor 542b in the transistor 500.

[0390] The insulator 550 functions as a gate insulator. It is preferable that the insulator 550 be placed in contact with the upper surface of the metal oxide 531c. The insulator 550 can be silicon oxide, silicon oxynitride, silicon nitride, silicon nitride, fluorine-added silicon oxide, carbon-added silicon oxide, carbon and nitrogen-added silicon oxide, or porous silicon oxide. Silicon oxide and silicon oxynitride are particularly preferred because they are thermally stable.

[0391] Similar to the insulator 524, it is preferable that the concentration of impurities such as water or hydrogen in the insulator 550 is reduced. The film thickness of the insulator 550 is preferably 1 nm or more and 20 nm or less.

[0392] In transistor 500, a metal oxide may be provided between the insulator 550 and the conductor 560. It is preferable that the metal oxide suppresses oxygen diffusion from the insulator 550 to the conductor 560. This allows the metal oxide to suppress oxidation of the conductor 560 by oxygen in the insulator 550.

[0393] The metal oxide may function as part of the gate insulator. Therefore, when silicon oxide or silicon oxynitride is used for the insulator 550, it is preferable to use a metal oxide that is a high-k material with a high dielectric constant. By making the gate insulator a laminated structure of insulator 550 and the metal oxide, a laminated structure that is stable against heat and has a high dielectric constant can be made. Therefore, in the transistor 500, it becomes possible to reduce the gate potential applied during transistor operation while maintaining the physical film thickness of the gate insulator. In addition, it becomes possible to thin the equivalent oxide film thickness (EOT) of the insulator that functions as a gate insulator.

[0394] Specifically, the metal oxide can be one or more selected from, for example, hafnium, aluminum, gallium, yttrium, zirconium, tungsten, titanium, tantalum, nickel, germanium, and magnesium. In particular, it is preferable to use an insulator containing oxides of one or both aluminum and hafnium, such as aluminum oxide, hafnium oxide, or an oxide containing aluminum and hafnium (hafnium aluminate).

[0395] Although the conductor 560 is shown as a two-layer structure in Figure 37, it may also be a single-layer structure or a laminated structure of three or more layers.

[0396] It is preferable to use a conductor 560a that has the function of suppressing the diffusion of impurities such as hydrogen atoms, hydrogen molecules, water molecules, nitrogen atoms, nitrogen molecules, nitrogen oxide molecules (e.g., N2O, NO, or NO2), or copper atoms. Alternatively, it is preferable to use a conductive material that has the function of suppressing the diffusion of oxygen (e.g., at least one such as oxygen atoms and oxygen molecules).

[0397] The conductor 560a has the function of suppressing oxygen diffusion, thereby preventing the conductor 560b from oxidizing due to oxygen contained in the insulator 550 and reducing its conductivity. It is preferable to use, for example, tantalum, tantalum nitride, ruthenium, or ruthenium oxide as a conductive material that has the function of suppressing oxygen diffusion.

[0398] The conductor 560b is preferably made of a conductive material mainly composed of tungsten, copper, or aluminum. Furthermore, since the conductor 560 also functions as wiring, it is preferable to use a conductor with high conductivity. For example, a conductive material mainly composed of tungsten, copper, or aluminum can be used. The conductor 560b may also have a laminated structure. For example, it may have a laminated structure of titanium or titanium nitride and the above-mentioned conductive material.

[0399] As shown in Figures 37A and 37C, in the region of the metal oxide 531b that does not overlap with the conductor 542, in other words, in the channel-forming region of the metal oxide 531, the side surface of the metal oxide 531 is covered by the conductor 560. This makes it easier to apply the electric field of the conductor 560, which functions as the first gate electrode, to the side surface of the metal oxide 531. Therefore, the on-current of the transistor 500 can be increased and the frequency characteristics can be improved.

[0400] The insulator 554 preferably functions as a barrier insulating film that suppresses the ingress of impurities such as water or hydrogen into the transistor 500 from the insulator 580 side, similar to the insulator 514, for example. For example, the insulator 554 preferably has lower hydrogen permeability than the insulator 524. Furthermore, as shown in Figures 37B and 37C, the insulator 554 preferably contacts the side surface of the metal oxide 531c, the top and side surfaces of the conductor 542a, the top and side surfaces of the conductor 542b, the side surfaces of the metal oxide 531a and metal oxide 531b, and the top surface of the insulator 524. With this configuration, the insulator 554 can suppress the ingress of hydrogen contained in the insulator 580 into the metal oxide 531 from the top or side surfaces of the conductor 542a, conductor 542b, metal oxide 531a, metal oxide 531b, and insulator 524.

[0401] Furthermore, it is preferable that the insulator 554 has the function of suppressing the diffusion of oxygen (for example, at least one such as oxygen atoms and oxygen molecules) (i.e., it is difficult for the above-mentioned oxygen to permeate through it). For example, it is preferable that the insulator 554 has lower oxygen permeability than the insulator 580 or the insulator 524.

[0402] The insulator 554 is preferably deposited using a sputtering method. By depositing the insulator 554 using a sputtering method in an oxygen-containing atmosphere, oxygen can be added to the vicinity of the region of the insulator 524 that is in contact with the insulator 554. As a result, the insulator 554 can supply oxygen to the metal oxide 531 from that region through the insulator 524. Here, the insulator 554 has a function to suppress upward diffusion of oxygen, thereby preventing oxygen from diffusing from the metal oxide 531 to the insulator 580. In addition, the insulator 522 has a function to suppress downward diffusion of oxygen, thereby preventing oxygen from diffusing from the metal oxide 531 to the substrate side. In this way, oxygen is supplied to the channel formation region of the metal oxide 531. This reduces oxygen deficiency in the metal oxide 531 and suppresses normally-on formation of the transistor.

[0403] As the insulator 554, for example, an insulator containing an oxide of one or both of aluminum and hafnium may be formed as a film. It is preferable to use, for example, aluminum oxide, hafnium oxide, or an oxide containing both aluminum and hafnium (hafnium aluminate) as the insulator containing an oxide of one or both of aluminum and hafnium.

[0404] The insulator 554, which has barrier properties against hydrogen, covers the insulators 524, 550, and 531, thereby separating the insulator 580 from the insulators 524, 531, and 550. As a result, the insulator 554 can prevent impurities such as hydrogen from entering the transistor 500 from the outside. Therefore, the transistor 500 can be given good electrical characteristics and reliability.

[0405] The insulator 580 is provided on the insulator 524, the metal oxide 531, and the conductor 542 via the insulator 554. For example, the insulator 580 is preferably made of silicon oxide, silicon oxynitride, silicon nitride, fluorine-added silicon oxide, carbon-added silicon oxide, carbon and nitrogen-added silicon oxide, or porous silicon oxide. Silicon oxide and silicon oxynitride are particularly preferred because they are thermally stable. Materials such as silicon oxide, silicon oxynitride, or porous silicon oxide are particularly preferred because they can easily form regions containing oxygen that is desorbed by heating.

[0406] It is preferable that the insulator 580 has a reduced concentration of impurities such as water or hydrogen in the film. Furthermore, the upper surface of the insulator 580 may be flattened.

[0407] The insulator 574 preferably functions as a barrier insulating film that suppresses the mixing of impurities, such as water or hydrogen, into the insulator 580 from above, similar to the insulator 514, for example. For the insulator 574, any insulator that can be used for insulator 514 or insulator 554, for example, may be used.

[0408] It is preferable that the insulator 581, which functions as an interlayer film, is provided on top of the insulator 574. It is preferable that the insulator 581, like the insulator 524, has a reduced concentration of impurities such as water or hydrogen in the film.

[0409] Conductors 545a and 545b are arranged in openings formed in insulators 581, 574, 580, and 554. Conductors 545a and 545b are also provided facing each other with conductor 560 in between. The height of the upper surfaces of conductors 545a and 545b may be on the same plane as the upper surface of insulator 581.

[0410] Furthermore, the insulator 541a is provided in contact with the inner walls of the openings of insulators 581, 574, 580, and 554. Also, the first conductor of the conductor 545a is formed in contact with the side surface of insulator 541a. Conductor 542a is located in at least a portion of the bottom of the opening and is in contact with conductor 545a. Similarly, the insulator 541a is provided in contact with the inner walls of the openings of insulators 581, 574, 580, and 554. Also, the first conductor of the conductor 545b is formed in contact with the side surface of insulator 541b. Conductor 542b is located in at least a portion of the bottom of the opening and is in contact with conductor 545b.

[0411] It is preferable that the conductors 545a and 545b are made of conductive materials mainly composed of tungsten, copper, or aluminum. Furthermore, the conductors 545a and 545b may be arranged in a laminated structure.

[0412] When the conductor 545 has a laminated structure, it is preferable to use a conductor that has the function of suppressing the diffusion of impurities such as water or hydrogen, as described above, for the conductors that come into contact with the metal oxide 531a, metal oxide 531b, conductor 542, insulator 554, insulator 580, insulator 574, and insulator 581. For example, it is preferable to use tantalum, tantalum nitride, titanium, titanium nitride, ruthenium, or ruthenium oxide. Furthermore, the conductive material that has the function of suppressing the diffusion of impurities such as water or hydrogen may be used in a single layer or a laminate. By using the conductive material, it is possible to suppress the absorption of oxygen added to the insulator 580 into the conductors 545a and 545b. In addition, it is possible to suppress the mixing of impurities such as water or hydrogen from the layer above the insulator 581 into the metal oxide 531 through the conductors 545a and 545b.

[0413] For insulators 541a and 541b, any insulator that can be used for insulator 554, for example, may be used. Since insulators 541a and 541b are provided in contact with insulator 554, it is possible to suppress the mixing of impurities such as water or hydrogen from, for example, insulator 580, etc., into the metal oxide 531 through conductors 545a and 545b. In addition, insulators 541a and 541b can suppress the absorption of oxygen contained in insulator 580 into conductors 545a and 545b.

[0414] Although not shown in the figures, conductors functioning as wiring may be placed in contact with the upper surfaces of conductor 545a and conductor 545b. It is preferable that the conductors functioning as wiring are made of a conductive material mainly composed of tungsten, copper, or aluminum. Furthermore, the conductors may have a laminated structure. For example, they may be laminated with titanium or titanium nitride and the conductive material. The conductors may also be formed to be embedded in openings provided in the insulator.

[0415] <Materials used in transistors> This section describes the constituent materials that can be used in transistors.

[0416] [substrate] As a substrate for forming transistor 500, for example, an insulating substrate, a semiconductor substrate, or a conductive substrate may be used. Examples of insulating substrates include glass substrates, quartz substrates, sapphire substrates, stabilized zirconia substrates (e.g., yttria-stabilized zirconia substrates), or resin substrates. Examples of semiconductor substrates include silicon or germanium semiconductor substrates, or compound semiconductor substrates made of silicon carbide, silicon germanium, gallium arsenide, indium phosphide, zinc oxide, or gallium oxide. Furthermore, there are semiconductor substrates having insulating regions within the aforementioned semiconductor substrates (e.g., SOI (Silicon On Insulator) substrates). Examples of conductive substrates include graphite substrates, metal substrates, alloy substrates, or conductive resin substrates. Furthermore, there are substrates having metal nitrides or metal oxides. Furthermore, the substrate may include, for example, a substrate on which a conductor or semiconductor is provided on an insulating substrate, a substrate on which a conductor or insulator is provided on a semiconductor substrate, or a substrate on which a semiconductor or insulator is provided on a conductive substrate. In addition, the substrate may be one on which elements are provided. Examples of elements provided on the substrate include capacitive elements, resistive elements, switch elements, light-emitting elements, or memory elements.

[0417] [Insulator] Examples of insulators include insulating oxides, nitrides, oxidized nitrides, nitride oxides, metal oxides, metal oxidized nitrides, or metal nitride oxides.

[0418] For example, in transistors, as miniaturization and integration increase, the thinning of the gate insulator can lead to problems such as leakage current. By using a high-k material for the insulator that functions as the gate insulator, it is possible to lower the voltage during transistor operation while maintaining the physical film thickness. On the other hand, by using a material with a low dielectric constant for the insulator that functions as the interlayer film, parasitic capacitance between wiring can be reduced. Therefore, the material of the insulator should be selected according to its function.

[0419] Examples of insulators with high dielectric constants include gallium oxide, hafnium oxide, zirconium oxide, oxides containing aluminum and hafnium, oxides containing aluminum and hafnium, oxides containing silicon and hafnium, oxides containing silicon and hafnium, or nitrides containing silicon and hafnium.

[0420] Examples of insulators with low dielectric constants include silicon oxide, silicon oxide nitride, silicon oxide nitride, silicon nitride, silicon oxide with added fluorine, silicon oxide with added carbon, silicon oxide with added carbon and nitrogen, silicon oxide with vacancies, or resins.

[0421] Transistors using oxide semiconductors can have their electrical characteristics stabilized by surrounding them with an insulator that has the function of suppressing the permeation of impurities such as hydrogen and oxygen (for example, insulators 514, 522, 554, and 574). For example, as an insulator that has the function of suppressing the permeation of impurities such as hydrogen and oxygen, an insulator containing boron, carbon, nitrogen, oxygen, fluorine, magnesium, aluminum, silicon, phosphorus, chlorine, argon, gallium, germanium, yttrium, zirconium, lanthanum, neodymium, hafnium, or tantalum can be used in a single layer or multilayer configuration. Specifically, as an insulator that has the function of suppressing the permeation of impurities such as hydrogen and oxygen, for example, metal oxides such as aluminum oxide, magnesium oxide, gallium oxide, germanium oxide, yttrium oxide, zirconium oxide, lanthanum oxide, neodymium oxide, hafnium oxide, or tantalum oxide, or metal nitrides such as aluminum nitride, titanium aluminum nitride, titanium nitride, silicon oxide nitride, or silicon nitride can be used.

[0422] The insulator that functions as a gate insulator is preferably an insulator that has a region containing oxygen that is released by heating. For example, silicon oxide or silicon oxynitride having a region containing oxygen that is released by heating can be structured to be in contact with the metal oxide 531, thereby compensating for the oxygen deficiency of the metal oxide 531.

[0423] [conductor] As a conductor, it is preferable to use a metallic element selected from, for example, aluminum, chromium, copper, silver, gold, platinum, tantalum, nickel, titanium, molybdenum, tungsten, hafnium, vanadium, niobium, manganese, magnesium, zirconium, beryllium, indium, ruthenium, iridium, strontium, and lanthanum, an alloy composed of the above metallic elements, or an alloy combining the above metallic elements. For example, it is preferable to use tantalum nitride, titanium nitride, tungsten, nitrides containing titanium and aluminum, nitrides containing tantalum and aluminum, ruthenium oxide, ruthenium nitride, oxides containing strontium and ruthenium, or oxides containing lanthanum and nickel. Furthermore, tantalum nitride, titanium nitride, nitrides containing titanium and aluminum, nitrides containing tantalum and aluminum, ruthenium oxide, ruthenium nitride, oxides containing strontium and ruthenium, or oxides containing lanthanum and nickel are preferred because they are conductive materials that are resistant to oxidation or maintain conductivity even when absorbing oxygen. Furthermore, as the conductor, a semiconductor with high electrical conductivity, such as polycrystalline silicon containing impurity elements like phosphorus, or a silicide such as nickel silicide may be used.

[0424] Multiple conductive materials formed from the above materials may be used as a conductor by stacking them. For example, a laminated structure may be formed by combining the aforementioned metal element material with an oxygen-containing conductive material. Alternatively, a laminated structure may be formed by combining the aforementioned metal element material with a nitrogen-containing conductive material. Furthermore, a laminated structure may be formed by combining the aforementioned metal element material with an oxygen-containing conductive material and a nitrogen-containing conductive material.

[0425] Furthermore, when using a metal oxide in the channel formation region of a transistor, it is preferable to use a laminated structure in the conductor that functions as the gate electrode, which combines a material containing the aforementioned metal element with a conductive material containing oxygen. In this case, it is preferable to provide the conductive material containing oxygen on the channel formation region side of the conductor. By providing the conductive material containing oxygen on the channel formation region side, oxygen released from the conductive material is more easily supplied to the channel formation region.

[0426] In particular, it is preferable to use a conductive material containing the metal element and oxygen contained in the metal oxide in which the channel is formed as the conductor functioning as the gate electrode. Alternatively, a conductive material containing the aforementioned metal element and nitrogen may be used as the conductor. For example, a conductive material containing nitrogen such as titanium nitride or tantalum nitride may be used. Alternatively, indium tin oxide, indium oxide containing tungsten oxide, indium zinc oxide containing tungsten oxide, indium oxide containing titanium oxide, indium tin oxide containing titanium oxide, indium zinc oxide, or silicon-doped indium tin oxide may be used. Alternatively, indium gallium zinc oxide containing nitrogen may be used. By using such materials, the conductor may be able to capture hydrogen contained in the metal oxide in which the channel is formed. It may also be able to capture hydrogen that is mixed in from, for example, an external insulator.

[0427] This embodiment can be implemented in appropriate combination with other embodiments described herein, at least in part.

[0428] The configuration shown in this embodiment can be used in appropriate combination with the configurations shown in other embodiments and examples.

[0429] (Embodiment 5) This embodiment describes metal oxides (hereinafter also referred to as oxide semiconductors) that can be used in the OS transistor described in the above embodiment.

[0430] <Classification of crystal structures> First, we will explain the classification of crystal structures in oxide semiconductors using Figure 38A. Figure 38A is a diagram illustrating the classification of crystal structures in oxide semiconductors, specifically IGZO (a metal oxide containing In, Ga, and Zn).

[0431] As shown in Figure 38A, oxide semiconductors are broadly classified into "Amorphous," "Crystalline," and "Crystal." "Amorphous" includes completely amorphous materials. "Crystalline" includes CAAC (c-axis-aligned crystalline), nc (nanocrystalline), and CAC (cloud-aligned composite) (excluding single crystal and polycrystal). Note that single crystal, polycrystal, and completely amorphous materials are excluded from the "Crystalline" classification. "Crystal" includes single crystal and polycrystal materials.

[0432] The structure within the thick frame shown in Figure 38A represents an intermediate state between "Amorphous" and "Crystal," and belongs to a new boundary region (New crystalline phase). In other words, this structure can be described as being different from "Crystal" or the energetically unstable "Amorphous."

[0433] The crystal structure of a film or substrate can be evaluated using X-ray diffraction (XRD) spectroscopy. Figure 38B shows the XRD spectrum obtained by GIXD (Grazing-Incidence XRD) measurement of a CAAC-IGZO film classified as "Crystalline" (the horizontal axis is 2θ [deg.], and the vertical axis represents intensity in arbitrary units (au)). The GIXD method is also called the thin-film method or the Seemann-Bohlin method. Hereafter, the XRD spectrum obtained by the GIXD measurement shown in Figure 38B will be simply referred to as the XRD spectrum. The composition of the CAAC-IGZO film shown in Figure 38B is approximately In:Ga:Zn = 4:2:3 [atomic ratio]. The thickness of the CAAC-IGZO film shown in Figure 38B is 500 nm.

[0434] As shown in Figure 38B, a clear peak indicating crystallinity is detected in the XRD spectrum of the CAAC-IGZO film. Specifically, a peak indicating c-axis orientation is detected near 2θ=31° in the XRD spectrum of the CAAC-IGZO film. As shown in Figure 38B, the peak near 2θ=31° is asymmetrical with respect to the angle at which the peak intensity was detected.

[0435] The crystal structure of a film or substrate can be evaluated by the diffraction pattern (also called the nano-beam electron diffraction pattern) observed using nano-beam electron diffraction (NBED). Figure 38C shows the diffraction pattern of a CAAC-IGZO film. Note that Figure 38C shows the diffraction pattern observed by NBED with the electron beam incident parallel to the substrate. The composition of the CAAC-IGZO film shown in Figure 38C is approximately In:Ga:Zn = 4:2:3 [atomic ratio]. Furthermore, in nano-beam electron diffraction, electron diffraction is performed with a probe diameter of 1 nm.

[0436] As shown in Figure 38C, the diffraction pattern of the CAAC-IGZO film shows multiple spots indicating c-axis orientation.

[0437] [Structure of oxide semiconductors] Note that when focusing on structure, oxide semiconductors may be classified differently from those shown in Figure 38A. For example, oxide semiconductors can be divided into single-crystal oxide semiconductors and other non-single-crystal oxide semiconductors. Examples of non-single-crystal oxide semiconductors include the aforementioned CAAC-OS and nc-OS. Furthermore, non-single-crystal oxide semiconductors include, for example, polycrystalline oxide semiconductors, pseudo-amorphous oxide semiconductors (a-like OS), and amorphous oxide semiconductors.

[0438] Here, we will explain the details of the CAAC-OS, nc-OS, and a-like OS mentioned above.

[0439] [CAAC-OS] CAAC-OS is an oxide semiconductor having multiple crystalline regions, the c-axis of these crystalline regions being oriented in a specific direction. This specific direction is the thickness direction of the CAAC-OS film, the normal direction to the surface on which the CAAC-OS film is formed, or the normal direction to the surface of the CAAC-OS film. A crystalline region is a region with periodic atomic arrangement. If the atomic arrangement is considered a lattice arrangement, then a crystalline region is also a region with a aligned lattice arrangement. Furthermore, CAAC-OS has regions where multiple crystalline regions are connected in the ab-plane direction. These regions may exhibit distortion. Distortion refers to a point in the region where multiple crystalline regions are connected where the orientation of the lattice arrangement changes between a region with a aligned lattice arrangement and another region with a aligned lattice arrangement. In short, CAAC-OS is an oxide semiconductor that is c-axis oriented and does not exhibit clear orientation in the ab-plane direction.

[0440] Each of the above-mentioned crystalline regions is composed of one or more minute crystals (crystals with a maximum diameter of less than 10 nm). When a crystalline region is composed of one minute crystal, the maximum diameter of that crystalline region is less than 10 nm. When a crystalline region is composed of multiple minute crystals, the maximum diameter of that crystalline region may be around several tens of nm.

[0441] In In-M-Zn oxide (where element M is one or more elements selected from, for example, aluminum, gallium, yttrium, tin, and titanium), CAAC-OS tends to have a layered crystalline structure (also called a layered structure) consisting of layers containing indium (In) and oxygen (hereinafter referred to as the In layer) and layers containing element M, zinc (Zn), and oxygen (hereinafter referred to as the (M,Zn) layer). Indium and element M are mutually substitutable. Therefore, the (M,Zn) layer may contain indium. The In layer may also contain element M. The In layer may also contain Zn. This layered structure can be observed, for example, as a lattice image in high-resolution TEM (Transmission Electron Microscope) images.

[0442] When structural analysis of a CAAC-OS film is performed using, for example, an XRD instrument, a peak indicating c-axis orientation is detected at 2θ = 31° or nearby in out-of-plane XRD measurements using θ / 2θ scanning. Note that the position of the peak indicating c-axis orientation (value of 2θ) may vary depending on the type and composition of the metal elements constituting the CAAC-OS.

[0443] Furthermore, for example, multiple bright spots are observed in the electron diffraction pattern of a CAAC-OS film. These spots are observed at point-symmetric positions with respect to the incident electron beam spot (also called the direct spot) that passed through the sample.

[0444] When the crystalline region of CAAC-OS is observed from the specific direction described above, the lattice arrangement within that region is based on a hexagonal lattice. However, the unit cell of this lattice arrangement is not necessarily a regular hexagon and may be non-regular hexagonal. Furthermore, CAAC-OS may have lattice arrangements such as pentagons or heptagons in the strained state described above. Moreover, it is difficult to confirm clear grain boundaries even near the strained state of CAAC-OS. In other words, it can be seen that the formation of grain boundaries is suppressed in CAAC-OS due to the strain in its lattice arrangement. This may be because CAAC-OS can tolerate strain due to factors such as the sparse arrangement of oxygen atoms in the ab-plane direction, or the change in interatomic bond distances due to the substitution of metal atoms.

[0445] A crystal structure in which clear grain boundaries are observed is called a polycrystalline material. Grain boundaries act as recombination centers, trapping carriers. Therefore, they are highly likely to cause, for example, a decrease in the on-current of a transistor or a decrease in field-effect mobility. Thus, CAAC-OS, in which clear grain boundaries are not observed, is one of the crystalline oxides that has a crystal structure suitable for the semiconductor layer of a transistor. In addition, a configuration containing Zn is preferred for CAAC-OS. For example, In-Zn oxide and In-Ga-Zn oxide are preferred because they can suppress the generation of grain boundaries more than In oxide.

[0446] CAAC-OS is an oxide semiconductor with high crystallinity and no clearly defined grain boundaries. Therefore, CAAC-OS is less susceptible to the decrease in electron mobility caused by grain boundaries. Furthermore, the crystallinity of oxide semiconductors can decrease due to factors such as the inclusion of impurities and the generation of defects. Therefore, CAAC-OS can be considered an oxide semiconductor with few impurities and defects (e.g., oxygen vacancies). Consequently, oxide semiconductors containing CAAC-OS have stable physical properties. Therefore, oxide semiconductors containing CAAC-OS are heat-resistant and highly reliable. In addition, CAAC-OS is stable even at high temperatures (so-called thermal budget) during the manufacturing process. Therefore, using CAAC-OS in OS transistors allows for greater flexibility in the manufacturing process of those OS transistors.

[0447] [nc-OS] nc-OS exhibits periodicity in atomic arrangement in minute regions (e.g., regions between 1 nm and 10 nm, particularly between 1 nm and 3 nm). In other words, nc-OS contains minute crystals. The size of these minute crystals is, for example, between 1 nm and 10 nm, particularly between 1 nm and 3 nm. For this reason, these minute crystals are also called nanocrystals. Furthermore, nc-OS does not show any regularity in crystal orientation between different nanocrystals. Therefore, no orientation is observed throughout the entire film. Consequently, depending on the analytical method, nc-OS may be indistinguishable from a-like OS and amorphous oxide semiconductors. For example, when structural analysis of an nc-OS film is performed using an XRD instrument, no peak indicating crystallinity is detected in out-of-plane XRD measurements using θ / 2θ scanning. Also, when electron diffraction (also called limited-field electron diffraction) is performed on an nc-OS film using an electron beam with a probe diameter larger than that of the nanocrystals (e.g., 50 nm or more), a diffraction pattern resembling a halo pattern is observed. On the other hand, when electron diffraction (also called nanobeam electron diffraction) is performed on an nc-OS film using an electron beam with a probe diameter close to or smaller than the size of the nanocrystal (for example, 1 nm to 30 nm), an electron diffraction pattern may be obtained in which multiple spots are observed within a ring-shaped region centered on a direct spot.

[0448] [a-like OS] a-like OS is an oxide semiconductor having a structure between nc-OS and amorphous oxide semiconductors. a-like OS has porous or low-density regions. In other words, a-like OS has lower crystallinity compared to nc-OS and CAAC-OS. Also, a-like OS has a higher hydrogen concentration in the film compared to nc-OS and CAAC-OS.

[0449] [Oxide semiconductor configuration] Next, we will explain the details of CAC-OS mentioned above. Note that CAC-OS refers to the material composition.

[0450] [CAC-OS] CAC-OS is a material composition in which, for example, the elements constituting the metal oxide are unevenly distributed in sizes of 0.5 nm to 10 nm, preferably 1 nm to 3 nm, or close to that size. In the following, a state in which one or more metal elements are unevenly distributed in a metal oxide, and the regions containing these metal elements are mixed in sizes of 0.5 nm to 10 nm, preferably 1 nm to 3 nm, or close to that size, is also referred to as a mosaic or patchy state.

[0451] Furthermore, CAC-OS is a composite metal oxide having a mosaic-like structure formed by the separation of the material into a first region and a second region, and the first region being distributed within the film (hereinafter also referred to as a cloud-like structure). In other words, CAC-OS is a composite metal oxide having a structure in which the first region and the second region are mixed.

[0452] Here, the atomic ratios of In, Ga, and Zn to the metal elements constituting the CAC-OS in In-Ga-Zn oxide are denoted as [In], [Ga], and [Zn], respectively. For example, in the CAC-OS of In-Ga-Zn oxide, the first region is the region where [In] is greater than the [In] in the composition of the CAC-OS film. The second region is the region where [Ga] is greater than the [Ga] in the composition of the CAC-OS film. Alternatively, for example, the first region is the region where [In] is greater than the [In] in the second region, and [Ga] is smaller than the [Ga] in the second region. The second region is the region where [Ga] is greater than the [Ga] in the first region, and [In] is smaller than the [In] in the first region.

[0453] Specifically, the first region described above is a region whose main component is, for example, indium oxide or indium zinc oxide. The second region described above is a region whose main component is, for example, gallium oxide or gallium zinc oxide. In other words, the first region can be rephrased as a region whose main component is In. The second region can be rephrased as a region whose main component is Ga.

[0454] Furthermore, it may be difficult to observe a clear boundary between the first region and the second region described above.

[0455] For example, in CAC-OS in In-Ga-Zn oxide, EDX mapping obtained using energy-dispersive X-ray spectroscopy (EDX) confirms that it has a structure in which regions mainly composed of In (first region) and regions mainly composed of Ga (second region) are unevenly distributed and mixed.

[0456] Therefore, when CAC-OS is used in a transistor, the conductivity due to the first region of CAC-OS and the insulation due to the second region of CAC-OS work complementaryly to give CAC-OS the function of switching the transistor (on / off function). In other words, CAC-OS has a conductive function in part of the material and an insulating function in part of the material, and the material as a whole has the function of a semiconductor. That is, by separating the conductive function and the insulating function, both functions can be maximized. Therefore, by using CAC-OS in a transistor, the transistor can have a high on-current (I on This enables high field-effect mobility (μ) and good switching operation.

[0457] Oxide semiconductors can take on diverse structures, each possessing different properties. One embodiment of the present invention may include two or more of the following: amorphous oxide semiconductors, polycrystalline oxide semiconductors, a-like OS, CAC-OS, nc-OS, and CAAC-OS.

[0458] <Transistors containing oxide semiconductors> Next, we will explain the case where the above oxide semiconductor is used in a transistor.

[0459] By using the above-mentioned oxide semiconductor in transistors, it is possible to realize transistors with high field-effect mobility. Furthermore, it is possible to realize highly reliable transistors.

[0460] In particular, it is preferable to use an oxide containing indium (In), gallium (Ga), and zinc (Zn) (also referred to as "IGZO") as the semiconductor layer in which the transistor channel is formed. Alternatively, an oxide containing indium (In), aluminum (Al), and zinc (Zn) (also referred to as "IAZO") may be used as the semiconductor layer. Alternatively, an oxide containing indium (In), aluminum (Al), gallium (Ga), and zinc (Zn) (also referred to as "IAGZO") may be used as the semiconductor layer.

[0461] It is preferable to use an oxide semiconductor with a low carrier concentration for the transistor. For example, the carrier concentration of an oxide semiconductor is 1 × 10⁻⁶. 17 cm -3 The following is preferably 1 × 10 15 cm -3 More preferably 1 × 10 13 cm -3 More preferably 1 × 10 11 cm -3 More preferably 1 × 10 10 cm -3 It is less than 1 × 10 -9 cm -3 This concludes the explanation. Furthermore, to lower the carrier concentration in an oxide semiconductor, the defect level density in the oxide semiconductor can be reduced by lowering the impurity concentration in the oxide semiconductor. In this specification, a low impurity concentration and low defect level density are referred to as high-purity intrinsic or substantially high-purity intrinsic. Note that an oxide semiconductor with a low carrier concentration may be referred to as a high-purity intrinsic or substantially high-purity intrinsic oxide semiconductor.

[0462] High-purity intrinsic or substantially high-purity intrinsic oxide semiconductors have a low defect level density, which may result in a low trap level density.

[0463] Charges trapped in the trap levels of oxide semiconductors can take a long time to disappear and sometimes behave like fixed charges. Therefore, transistors in which channel formation regions are formed in oxide semiconductors with a high density of trap levels may exhibit unstable electrical properties.

[0464] Therefore, reducing the impurity concentration in the oxide semiconductor is effective in stabilizing the electrical characteristics of the transistor. Furthermore, in order to reduce the impurity concentration in the oxide semiconductor, it is preferable to also reduce the impurity concentration in adjacent films. Examples of impurities include hydrogen, nitrogen, alkali metals, alkaline earth metals, iron, nickel, or silicon.

[0465] <Impurities> Here, we will explain the effects of various impurities in oxide semiconductors.

[0466] In oxide semiconductors, the presence of silicon or carbon, which are both Group 14 elements, leads to the formation of defect levels in the oxide semiconductor. Therefore, the concentration of silicon or carbon in the oxide semiconductor (the concentration obtained by secondary ion mass spectrometry (SIMS)) is 2 × 10⁻¹⁰. 18 atoms / cm 3 The following is preferably 2 × 10 17 atoms / cm 3 The following applies:

[0467] When alkali metals or alkaline earth metals are present in oxide semiconductors, they can form defect levels and generate carriers. Therefore, transistors using oxide semiconductors containing alkali metals or alkaline earth metals tend to exhibit normally-on characteristics. For this reason, the concentration of alkali metals or alkaline earth metals in the oxide semiconductor obtained by SIMS should be set to 1 × 10⁻⁶. 18 atoms / cm 3 The following is preferably 2 × 10 16 atoms / cm 3 Do the following:

[0468] In oxide semiconductors, the presence of nitrogen increases the carrier concentration due to the generation of electrons, which act as carriers, making it more likely to become n-type. As a result, transistors using oxide semiconductors containing nitrogen tend to exhibit normally-on characteristics. Alternatively, the presence of nitrogen in oxide semiconductors can lead to the formation of trap levels. This can result in unstable electrical properties of the transistor. Therefore, the nitrogen concentration in oxide semiconductors obtained by SIMS should be set to 5 × 10⁻⁶. 19 atoms / cm 3 Less than 5 × 10 18 atoms / cm 3 More preferably 1 × 10 18 atoms / cm 3 More preferably 5 × 10 17 atoms / cm 3 Do the following:

[0469] Hydrogen contained in oxide semiconductors reacts with oxygen bonded to metal atoms to form water, which can create oxygen vacancies in the oxide semiconductor. Furthermore, hydrogen can fill these oxygen vacancies, generating electrons, which act as carriers. In addition, some of the hydrogen can combine with oxygen bonded to metal atoms to generate electrons, which also act as carriers. Therefore, transistors using oxide semiconductors containing hydrogen tend to exhibit normally-on characteristics. For this reason, it is preferable to reduce the hydrogen content in oxide semiconductors as much as possible. Specifically, the hydrogen concentration in the oxide semiconductor obtained by SIMS should be 1 × 10⁻⁶. 20 atoms / cm 3 Less than 1 × 10 19 atoms / cm 3 Less than 5x10 18 atoms / cm 3 Less than 1 × 10 18 atoms / cm 3 Make it less than.

[0470] By using an oxide semiconductor with sufficiently reduced impurities in the channel formation region of a transistor, stable electrical characteristics can be imparted to the transistor.

[0471] The configuration shown in this embodiment can be used in appropriate combination with the configurations shown in other embodiments and examples.

[0472] (Embodiment 6) This embodiment describes electronic equipment to which a semiconductor device according to one aspect of the present invention can be applied.

[0473] A semiconductor device according to one aspect of the present invention can be applied to the display unit of an electronic device. Therefore, one aspect of the present invention can realize an electronic device with high display quality. Alternatively, one aspect of the present invention can realize an electronic device with extremely high resolution. Alternatively, one aspect of the present invention can realize an electronic device with high reliability.

[0474] Electronic devices using semiconductor devices according to one aspect of the present invention include, for example, televisions, display devices such as monitors, lighting devices, desktop or notebook personal computers, word processors, and DVDs (Digital Versatile). Examples include image playback devices that play still images or videos stored on recording media such as discs, portable CD players, radios, tape recorders, headphone stereos, stereos, desk clocks, wall clocks, cordless telephone handsets, transceivers, car phones, mobile phones, personal digital assistants, tablet devices, portable game consoles, fixed game machines such as pachinko machines, calculators, electronic organizers, e-book readers, electronic translators, voice input devices, video cameras, digital still cameras, electric shavers, high-frequency heating devices such as microwave ovens, electric rice cookers, electric washing machines, electric vacuum cleaners, water heaters, electric fans, hair dryers, air conditioning equipment such as air conditioners, humidifiers, and dehumidifiers, dishwashers, dish dryers, clothes dryers, futon dryers, electric refrigerators, electric freezers, electric refrigerator-freezers, DNA storage freezers, flashlights, tools such as chainsaws, smoke detectors, or medical equipment such as dialysis machines. Furthermore, examples include industrial equipment such as guide lights, traffic lights, conveyor belts, elevators, escalators, industrial robots, power storage systems, or energy storage devices for power leveling and smart grids. Also, mobile devices propelled by engines using fuel or electric motors using electricity from energy storage devices may also fall under the category of electronic equipment. Examples of such mobile devices include electric vehicles (EVs), hybrid vehicles (HVs) that combine internal combustion engines and electric motors, plug-in hybrid vehicles (PHVs), tracked vehicles in which the tires and wheels of these vehicles are replaced with tracks, motorized bicycles including electric assist bicycles, motorcycles, electric wheelchairs, golf carts, small or large vessels, submarines, helicopters, aircraft, rockets, satellites, space probes, planetary probes, or spacecraft.

[0475] An electronic device according to one aspect of the present invention may have a secondary battery. Furthermore, it is preferable that the secondary battery can be charged using contactless power transmission.

[0476] Examples of secondary batteries include lithium-ion secondary batteries, nickel-metal hydride batteries, nickel-cadmium batteries, organic radical batteries, lead-acid batteries, air secondary batteries, nickel-zinc batteries, and silver-zinc batteries.

[0477] An electronic device according to one aspect of the present invention may have an antenna. By receiving signals with the antenna, the display unit can display images and information. Furthermore, if the electronic device has an antenna and a secondary battery, the antenna may be used for contactless power transmission.

[0478] An electronic device according to one aspect of the present invention may have sensors (including, for example, those with functions to measure force, displacement, position, velocity, acceleration, angular velocity, rotational speed, distance, light, liquid, magnetism, temperature, chemical substances, sound, time, hardness, electric field, current, voltage, power, radiation, flow rate, humidity, gradient, vibration, odor, or infrared radiation).

[0479] An electronic device according to one aspect of the present invention can have various functions. For example, it can have a function to display various information (e.g., still images, videos, or text images) on a display unit, a touch panel function, a function to display a calendar, date, or time, a function to execute various software (programs), a wireless communication function, or a function to read programs or data recorded on a recording medium.

[0480] Furthermore, electronic devices having multiple display units may have functions such as displaying image information primarily on one part of the display unit and text information primarily on another part, or displaying a three-dimensional image by displaying images that take parallax into account on multiple display units. Furthermore, electronic devices having an image receiving unit may have functions such as capturing still images or moving images, automatically or manually correcting captured images, saving captured images to a recording medium (external or built into the electronic device), or displaying captured images on a display unit. However, the functions of an electronic device according to one aspect of the present invention are not limited to these. An electronic device according to one aspect of the present invention may have a variety of functions.

[0481] A semiconductor device according to one aspect of the present invention can display high-resolution images. Therefore, it can be suitably used in portable electronic devices, wearable electronic devices, or e-book readers. For example, it can be suitably used in xR devices such as VR devices or AR devices.

[0482] Figure 39A shows the external appearance of the camera 8000 with the viewfinder 8100 attached.

[0483] The camera 8000 includes a housing 8001, a display unit 8002, operation buttons 8003, and a shutter button 8004, etc. A detachable lens 8006 is also attached to the camera 8000. The lens 8006 and the housing of the camera 8000 may be integrated into a single unit.

[0484] Camera 8000 can take an image by pressing the shutter button 8004 or by touching the display unit 8002, which functions as a touch panel.

[0485] The housing 8001 has a mount with electrodes, and in addition to the viewfinder 8100, it can be connected to, for example, a strobe device or the like.

[0486] The viewfinder 8100 includes a housing 8101, a display unit 8102, and buttons 8103, etc.

[0487] The housing 8101 is attached to the camera 8000 by a mount that engages with the camera 8000's mount. The viewfinder 8100 can, for example, display images or other data received from the camera 8000 on the display unit 8102.

[0488] Button 8103 has a function such as a power button.

[0489] A semiconductor device according to one aspect of the present invention can be applied to the display unit 8002 of a camera 8000 and the display unit 8102 of a viewfinder 8100. The viewfinder 8100 may be built into the camera 8000.

[0490] Figure 39B shows the external appearance of the head-mounted display 8200.

[0491] The head-mounted display 8200 includes a mounting section 8201, lenses 8202, a main unit 8203, a display unit 8204, and a cable 8205, among other components. The mounting section 8201 also has a built-in battery 8206.

[0492] Cable 8205 has the function of supplying power from battery 8206 to main unit 8203. Main unit 8203 is equipped with, for example, a wireless receiver and can display received video information on display unit 8204. In addition, main unit 8203 is equipped with, for example, a camera and can use information of the user's eyeball or eyelid movements as an input means.

[0493] Furthermore, the attachment unit 8201 may have a function to recognize gaze, for example, by providing a plurality of electrodes at a position that touches the user and is capable of detecting the current flowing in accordance with the user's eye movements. It may also have a function to monitor the user's pulse rate based on the current flowing through the electrodes. The attachment unit 8201 may also have various sensors, for example, a temperature sensor, a pressure sensor, or an acceleration sensor. The head-mounted display 8200 may have a function to display the user's biometric information on the display unit 8204, or a function to change the image displayed on the display unit 8204 in accordance with the user's head movements.

[0494] A semiconductor device according to one aspect of the present invention can be applied to a display unit 8204.

[0495] Figures 39C to 39E show the external appearance of the head-mounted display 8300. The head-mounted display 8300 includes a housing 8301, a display unit 8302, a band-shaped fixing device 8304, and a pair of lenses 8305.

[0496] The user can view the display on the display unit 8302 through the lens 8305. It is preferable that the head-mounted display 8300 has the display unit 8302 positioned in a curved shape, for example, as this allows the user to experience a greater sense of presence. Furthermore, by viewing different images displayed in different areas of the display unit 8302 through the lens 8305, it is possible to perform, for example, a three-dimensional display using parallax. The configuration is not limited to having only one display unit 8302; for example, two display units 8302 may be provided, with one display unit for each of the user's eyes.

[0497] A semiconductor device according to one aspect of the present invention can be applied to a display unit 8302. A semiconductor device according to one aspect of the present invention can also achieve extremely high resolution. For example, even when the display is magnified using the lens 8305 as shown in Figure 39E, the pixels are difficult for the user to see. In other words, the display unit 8302 can be used to allow the user to view a highly realistic image.

[0498] Figure 39F shows the external appearance of a goggle-type head-mounted display 8400. The head-mounted display 8400 has a pair of housings 8401, a mounting part 8402, and a cushioning member 8403. A display unit 8404 and a lens 8405 are provided inside each of the pair of housings 8401. The pair of display units 8404 can display different images from each other, enabling three-dimensional display using parallax.

[0499] The user can view the display on the display unit 8404 through the lens 8405. The lens 8405 has a focus adjustment mechanism and its position can be adjusted according to the user's eyesight. The display unit 8404 is preferably square or a horizontally elongated rectangle. This can enhance the sense of realism.

[0500] The mounting portion 8402 is preferably adjustable to the size of the user's face and has plasticity and elasticity to prevent it from slipping off. Furthermore, it is preferable that a part of the mounting portion 8402 has a vibration mechanism that functions as, for example, a bone conduction earphone. This eliminates the need for separate earphones or speakers, allowing users to enjoy video and audio simply by wearing the device. The housing 8401 may also have a function to output audio data via, for example, wireless communication.

[0501] The mounting portion 8402 and the cushioning member 8403 are parts that come into contact with the user's face (forehead, cheeks, etc.). By ensuring that the cushioning member 8403 is in close contact with the user's face, light leakage can be prevented, thereby enhancing the sense of immersion. It is preferable to use a soft material for the cushioning member 8403 so that it adheres closely to the user's face when the user wears the head-mounted display 8400. For example, materials such as rubber, silicone rubber, urethane, or sponge can be used. Furthermore, if a material such as sponge is covered with cloth or leather (genuine leather or synthetic leather), gaps are less likely to form between the user's face and the cushioning member 8403, effectively preventing light leakage. In addition, using such materials is preferable because it feels good against the skin and, for example, prevents the user from feeling cold when wearing it in cold weather. It is preferable that the components that come into contact with the user's skin, such as the cushioning member 8403 or the mounting portion 8402, are removable, as this facilitates cleaning or replacement.

[0502] Figure 40A shows an example of a television system. The television system 7100 has a display unit 7000 incorporated into a housing 7101. Here, the housing 7101 is shown supported by a stand 7103.

[0503] In Figure 40A, a semiconductor device according to one aspect of the present invention can be applied to a display unit 7000.

[0504] The television device 7100 shown in Figure 40A can be operated by operating switches on the housing 7101 or by a separate remote control unit 7111. Alternatively, the display unit 7000 may be equipped with a touch sensor, allowing the television device 7100 to be operated by, for example, touching the display unit 7000 with a finger. The remote control unit 7111 may have a display unit that displays information output from the remote control unit 7111. The television device 7100 can operate channels or volume using the operating keys or touch panel on the remote control unit 7111. It can also operate the image displayed on the display unit 7000.

[0505] The television system 7100 can be configured to include, for example, a receiver and a modem. The receiver can receive general television broadcasts. Furthermore, by connecting to a wired or wireless communication network via the modem, it is possible to perform one-way (from sender to receiver) or two-way (for example, between sender and receiver, or between receivers) information communication.

[0506] Figure 40B shows an example of a notebook personal computer. The notebook personal computer 7200 has a casing 7211, a keyboard 7212, a pointing device 7213, and an external connection port 7214, etc. A display unit 7000 is incorporated into the casing 7211.

[0507] In Figure 40B, a semiconductor device according to one aspect of the present invention can be applied to a display unit 7000.

[0508] Figures 40C and 40D show examples of digital signage.

[0509] The digital signage 7300 shown in Figure 40C includes a housing 7301, a display unit 7000, and a speaker 7303, etc. Furthermore, it may include LED lamps, operation keys (including a power switch or operation switch), connection terminals, various sensors, or a microphone, etc.

[0510] Figure 40D shows a digital signage system mounted on a cylindrical column. The digital signage system 7400 has a display unit 7000 that is provided along the curved surface of the column 7401.

[0511] In Figures 40C and 40D, a semiconductor device according to one aspect of the present invention can be applied to a display unit 7000.

[0512] The larger the display area of ​​the Digital Signage 7300 or Digital Signage 7400, the more information can be displayed at once. Furthermore, a larger display area makes it more eye-catching, which can, for example, enhance the effectiveness of advertisements.

[0513] Furthermore, it is preferable to apply a touch panel to the display unit 7000 of the digital signage 7300 or digital signage 7400. This allows not only images or videos to be displayed on the display unit 7000, but also to be operated intuitively by the user. In addition, when used for purposes such as providing route information or traffic information, intuitive operation can enhance usability.

[0514] Furthermore, as shown in Figures 40C and 40D, it is preferable that the digital signage 7300 or digital signage 7400 can be linked wirelessly with an information terminal 7311 or information terminal 7411, such as a smartphone owned by the user. For example, the advertising information displayed on the display unit 7000 can be displayed on the screen of the information terminal 7311 or information terminal 7411. Also, the display on the display unit 7000 can be switched by operating the information terminal 7311 or information terminal 7411.

[0515] Furthermore, the digital signage 7300 or digital signage 7400 can also run games using the screen of the information terminal 7311 or information terminal 7411 as the control device (controller). This allows a large number of users to participate in and enjoy the game simultaneously.

[0516] Figure 40E shows an example of an information terminal. The information terminal 7550 includes a housing 7551, a display unit 7552, a microphone 7557, a speaker unit 7554, a camera 7553, and an operation switch 7555. A semiconductor device according to one aspect of the present invention can be applied to the display unit 7552. The display unit 7552 can also function as a touch panel. Furthermore, the information terminal 7550 can be equipped with an antenna and a battery inside the housing 7551. The information terminal 7550 can be used, for example, as a smartphone, a mobile phone, a tablet information terminal, a tablet personal computer, or an e-book reader.

[0517] Figure 40F shows an example of a wristwatch-type information terminal. The information terminal 7660 includes a housing 7661, a display unit 7662, a band 7663, a buckle 7664, an operation switch 7665, and input / output terminals 7666. The information terminal 7660 may also include, for example, an antenna and a battery inside the housing 7661. The information terminal 7660 can run various applications, such as mobile phone calls, email, document viewing and creation, music playback, internet communication, or computer games.

[0518] Furthermore, the information terminal 7660 is equipped with a touch sensor on the display unit 7662, allowing it to be operated by touching the screen with a finger or stylus, for example. For example, touching the icon 7667 displayed on the display unit 7662 can launch an application. The operation switch 7665 can have various functions, such as setting the time, turning the power on or off, turning wireless communication on or off, activating or deactivating silent mode, or activating or deactivating power saving mode. For example, the functions of the operation switch 7665 can also be configured by the operating system built into the information terminal 7660.

[0519] Furthermore, the information terminal 7660 is capable of performing standardized short-range wireless communication. For example, it can communicate with a wireless communication-enabled headset to make hands-free calls. The information terminal 7660 can also send and receive data with other information terminals via the input / output terminal 7666. It can also be charged via the input / output terminal 7666. Note that charging may be performed by wireless power supply without using the input / output terminal 7666.

[0520] Figure 41A shows the exterior of the automobile 9700. Figure 41B shows the driver's seat of the automobile 9700. The automobile 9700 includes a body 9701, wheels 9702, a dashboard 9703, and lights 9704, etc. A display device according to one aspect of the present invention can be used, for example, in the display unit of the automobile 9700. For example, a display device according to one aspect of the present invention can be applied to each of the display units 9710 to 9715 shown in Figure 41B.

[0521] Display units 9710 and 9711 are display devices installed on the windshield of an automobile. In one aspect of the present invention, the electrodes of the display device are made of a light-transmitting conductive material, thereby creating a so-called see-through display device that allows the other side to be seen through. A see-through display device does not obstruct the driver's view when the automobile 9700 is in operation. Therefore, the display device according to one aspect of the present invention can be installed on the windshield of the automobile 9700. If the display device is equipped with, for example, a transistor for driving the display device, it is preferable to use a light-transmitting transistor, such as an organic transistor using an organic semiconductor material or a transistor using an oxide semiconductor.

[0522] The display unit 9712 is a display device installed on the pillar. For example, by displaying images from an imaging device installed on the vehicle body 9701 on the display unit 9712, the field of view obstructed by the pillar can be compensated for. The display unit 9713 is a display device installed on the dashboard 9703. For example, by displaying images from an imaging device installed on the vehicle body 9701 on the display unit 9713, the field of view obstructed by the dashboard 9703 can be compensated for. In other words, the automobile 9700 can compensate for blind spots and enhance safety by displaying images from an imaging device installed on the vehicle body 9701 on the display units 9712 and 9713. Furthermore, by displaying images that compensate for the parts that are not visible, safety checks can be performed more naturally and without discomfort.

[0523] Figure 42 shows the interior of automobile 9700, which employs bench seats for the driver and passenger. Display unit 9721 is a display device installed in the door. For example, by displaying images from an imaging means installed in the vehicle body 9701 on display unit 9721, the view obstructed by the door can be compensated for. Display unit 9722 is a display device installed in the steering wheel. Display unit 9723 is a display device installed in the center of the seat surface of the bench seat.

[0524] Display units 9714, 9715, or 9722 can provide the user with various information by displaying, for example, navigation information, driving speed, engine RPM, mileage, fuel level, gear status, or air conditioning settings. The display items and layout displayed on the display units can be changed as appropriate to suit the user's preferences. The above information can also be displayed on one or more of the display units 9710 to 9713, 9721, and 9723. In addition, one or more of the display units 9710 to 9715 and 9721 to 9723 can also be used as lighting devices.

[0525] The configuration shown in this embodiment can be used in appropriate combination with the configurations shown in other embodiments and examples. [Examples]

[0526] This embodiment describes a display device that was actually fabricated. The display device is equipped with a high-resolution OLED display (also called an organic EL display) with a resolution of 3207 ppi using an oxide semiconductor FET with a channel length of 200 nm. This display device is suitably used in xR devices such as VR devices or AR devices. A semiconductor device according to one aspect of the present invention is suitably applied to the display device shown in this embodiment.

[0527] In this embodiment, an OS transistor (a transistor in which an oxide semiconductor is included in the semiconductor layer where the channel is formed) may be called an oxide semiconductor FET or OSFET. Similarly, a Si transistor (a transistor in which silicon is included in the semiconductor layer where the channel is formed) may be called a SiFET.

[0528] In this embodiment, for example, detailed descriptions of the display device, pixels, and oxide semiconductor FETs can be appropriately referenced from other embodiments. Therefore, in this embodiment, descriptions may be omitted as appropriate.

[0529] <Configuration of oxide semiconductor FET> This section describes the oxide semiconductor FET (OSFET700) used in the fabricated display device. Figure 43 shows the process flow of the OSFET700. Figure 44 is a schematic perspective view of the OSFET700. Figures 45A to 45D are STEM (Scanning Transmission Electron Microscope) images of the OSFET700 and the area around the OSFET700 in the pixels of the fabricated display device. Figure 45A is a planar STEM image of the OSFET700. Figures 45B and 45C are cross-sectional STEM images of the OSFET700 in the channel length direction. Figure 45D is a cross-sectional STEM image of the OSFET700 in the channel width direction.

[0530] First, in processes P01 and P02, the conductor 705 is formed (corresponding to the conductor 505 in Figure 37). The conductor 705 functions as the back gate electrode (BGE) of the OSFET 700. Next, in process P03, the insulators 722 and 724 are formed (corresponding to the insulators 522 and 524 in Figure 37). Next, in process P04, the metal oxide 731 and the conductor 742 are formed (corresponding to the metal oxide 531 and conductor 542 in Figure 37). The metal oxide 731 functions as the active layer of the OSFET 700. The conductor 742 also functions as the source and drain electrodes (S / D metal) of the OSFET 700. Next, in process P05, the insulator 754 is formed (corresponding to the insulators 554 and 580 in Figure 37). Next, in processes P06 and P07, an insulator 750 was formed (corresponding to insulator 550 in Figure 37). Insulator 750 functions as the gate insulating film (GI) of the OSFET 700. Next, in process P08, a conductor 760 was formed (corresponding to conductor 560 in Figure 37). Conductor 760 functions as the gate electrode (TGE) of the OSFET 700. Next, in process P09, a passivation film, interlayer films, vias (sometimes called contacts), and wiring were formed (not shown).

[0531] The active layer (metal oxide 731) of OSFET700 uses IGZO (also called CAAC-IGZO) with a CAAC structure. Tantalum nitride is used for the S / D metal (conductor 742). OSFET700 is a self-align type in which the channel is formed simultaneously with the formation of the TGE (conductor 760). Furthermore, the controllability of the channel is improved by the placement of BGE (conductor 705).

[0532] The fabricated display device uses an oxide semiconductor as the backplane, and has a configuration in which layers containing an OSFET, a capacitor, two layers of wiring, pixel electrodes, and an OLED are stacked sequentially on a Si substrate (sometimes referred to as OSFET\capacitor\two layers of wiring\pixel electrodes\OLED).

[0533] A semiconductor device 100B according to one aspect of the present invention, as shown in Embodiment 2 (see Figure 16), was applied to the pixels of the fabricated display device. The pixels have a configuration comprising seven oxide semiconductor FETs and three capacitors (sometimes referred to as a 7Tr3C configuration).

[0534] Furthermore, the OSFET700 in the pixels of the fabricated display device has a channel length of 200 nm and a channel width of 130 nm. In addition, the OSFET700 has a Trigate structure in which the top and sides of the active layer (metal oxide 731) are covered with TGE (conductor 760).

[0535] <Electrical characteristics of oxide semiconductor FETs> This section describes the evaluation results of the electrical characteristics of the fabricated oxide semiconductor FET (OSFET700).

[0536] [Id-Vg characteristics] Figure 46 is a graph showing the evaluation results of the Id-Vg characteristics of OSFET700. The evaluated OSFET700 has a channel length of 200 nm and a channel width of 130 nm. The Id-Vg characteristics were evaluated by setting the potential applied to the back gate of the OSFET700 to the same potential applied to the gate. In Figure 46, the horizontal axis shows the voltage between the source and gate (also called voltage Vg), and the vertical axis shows the current flowing between the source and drain (also called current Id). Figure 46 shows the current Id in the range of voltage Vg from -4V to 4V. Figure 46 also shows the Id-Vg characteristics when the voltage between the source and drain (also called voltage Vd) is 0.1V and 1.2V. Curve 811 is the Id-Vg characteristic when the voltage Vd is 0.1V. Curve 812 is the Id-Vg characteristic when the voltage Vd is 1.2V.

[0537] The Id-Vg characteristics shown in Figure 46 indicate that the OSFET700 is a normally-off type with a sufficient on-off ratio. Furthermore, the S-value of the OSFET700 was 101 mV / decade. The off-current of the OSFET700 was also low enough to reach the lower limit of measurement.

[0538] During the operation of the display device, a high voltage is applied to the OSFET700 in each pixel. Therefore, the OSFET700 is designed so that the equivalent oxide thickness (EOT) of the GI (insulator 750) is 11 nm.

[0539] [Vth variation] Figure 47 is a cumulative frequency distribution diagram showing the evaluation results of the Vth variation of OSFET700. Figure 47 shows the Vth distribution of 72 OSFET700s. The configuration of the evaluated OSFET700 (channel length and channel width, etc.) is the same as that of the OSFET700 whose Id-Vg characteristics were evaluated as shown in Figure 46. The evaluation of Vth variation was performed by setting the potential applied to the back gate of the OSFET700 to the same potential applied to the gate. In this embodiment, in the Id-Vg characteristics shown in Figure 46, the current Id = 6 × 10⁻⁶ -8 Vth was defined as the voltage Vg at which A occurs. In Figure 47, the horizontal axis represents Vth, and the vertical axis represents the cumulative value.

[0540] As shown in the cumulative frequency distribution in Figure 47, the standard deviation σ, which is an indicator of Vth variability, was 93mV.

[0541] [Id-Vd characteristics] Figure 48A is a graph showing the evaluation results of the Id-Vd characteristics of OSFET700. The OSFET700 evaluated has the same configuration as the OSFET700 whose Id-Vg characteristics were evaluated in Figure 46, but with three FETs connected in series as shown in Figure 6B, forming a triple-gate type. The Id-Vd characteristics were evaluated by setting the potential applied to the back gate of the OSFET700 to the same potential applied to the source. In Figure 48A, the horizontal axis represents voltage Vd, and the vertical axis represents current Id. Figure 48A shows current Id in the range of voltage Vd from 0V to 6V. Figure 48A also shows multiple Id-Vd characteristics evaluated by varying the voltage Vg. Curve 831 is the Id-Vd characteristic when the voltage Vg is 2.000V. Curve 832 is the Id-Vd characteristic when the voltage Vg is 1.975V. Curve 833 shows the Id-Vd characteristics when the voltage Vg is 1.950V. Curve 834 shows the Id-Vd characteristics when the voltage Vg is 1.925V. Several other Id-Vd characteristics measured by varying the voltage Vg in 0.025V increments are also shown. Figure 48B shows the Id-Vd characteristics of a SiFET evaluated for comparison. The evaluated SiFET has a channel length of 230nm and a channel width of 1600nm. Curve 835 shows the Id-Vd characteristics when the voltage Vg is 3.3V. Curve 836 shows the Id-Vd characteristics when the voltage Vg is 1.8V.

[0542] The Id-Vd characteristics shown in Figures 48A and 48B demonstrate that the OSFET exhibited sufficient saturation characteristics at all voltages Vg compared to the SiFET. Furthermore, the Id-Vd characteristics shown in Figure 48A indicate that the current Id of the OSFET fluctuates in response to fine fluctuations in voltage Vg, demonstrating that precise current control during OLED light emission is possible.

[0543] [Vd withstand voltage] Figure 49 is a graph showing the evaluation results of the Vd breakdown voltage of OSFET700. The configuration of the evaluated OSFET700 is the same as that of the OSFET700 whose Id-Vg characteristics were evaluated, as shown in Figure 46. The Vd breakdown voltage evaluation was performed by setting the potential applied to the back gate of the OSFET700 to the same potential applied to the gate. In Figure 49, the horizontal axis represents voltage Vd, and the vertical axis represents current Id. Figure 49 shows the current Id in the range of voltage Vd from 0V to 30V when the voltage Vg is 0V. Curve 841 is the characteristic of the OSFET. Curve 842 is the characteristic of a SiFET evaluated for comparison. The configuration of the evaluated SiFET is the same as that of the SiFET whose Id-Vd characteristics were evaluated, as shown in Figure 48B.

[0544] In curve 841, the voltage Vd at which the current Id increases sharply is the Vd breakdown voltage. The OSFET700 had a Vd breakdown voltage of approximately 20V, which was higher than that of the SiFET.

[0545] [Off-current] As shown in the Id-Vg characteristics in Figure 46, the off-current of an oxide semiconductor FET is so low that it is difficult to measure using conventional measurement methods. Therefore, the off-current of the oxide semiconductor FET was quantitatively evaluated using the circuit shown in Figure 50. In Figure 50, the oxide semiconductor FET to be evaluated is connected to circuit section 851. The oxide semiconductor FET used to evaluate the off-current consists of 20,000 OSFET700s connected in parallel, each with a channel length of 200 nm and a channel width of 130 nm. As a result, the oxide semiconductor FET has a pseudo-channel width of 2.6 mm. Circuit section 852 controls the circuit to evaluate the off-current. Circuit section 853 outputs a signal for evaluating the off-current to output terminal 855. Signals to control the circuit for evaluating the off-current are input to the input terminal group 854. The off-current was evaluated by applying the potentials shown in Figure 50 to each terminal of circuit section 851.

[0546] Figure 51 is a graph showing the evaluation results of the off-current of an oxide semiconductor FET. In Figure 51, the horizontal axis represents the reciprocal of the temperature T, and the vertical axis represents the off-current (also called current Ioff). The off-current on the vertical axis is the value converted to a channel width of 130 nm for the OSFET700. The plots at points 861 to 864 represent the measured off-current at temperatures of 150°C, 125°C, 100°C, and 85°C, respectively. The line 865 is a regression line obtained from points 861 to 864. The off-current at room temperature of 27°C predicted from line 865 is 1 × 10⁻¹⁰ -24 It is less than A. Therefore, it has been shown that the off-current of the oxide semiconductor FET is a very low value.

[0547] <Display result from the display device> The display device fabricated in this embodiment includes a high-resolution OLED display (display 871) with a resolution of 3207 ppi. Table 1 shows the specifications of display 871. Oxide semiconductor FETs (OSFET700) were used as transistors constituting the pixels and gate drivers of display 871.

[0548] [Table 1]

[0549] Figure 52 shows the display results from display 871. As shown in Figure 52, a detailed and clear image was obtained. In addition to still images, a realistic video was also obtained.

[0550] Figure 53 shows the display result when only the right side (display surface 881) of the display 871 is displayed in white. The brightness of the non-emissive area (black area) on the left half (display surface 882) of the display 871 is 0.002 cd / m². 2 Therefore, the brightness of the light-emitting area (white area) on the right half (display surface 881) of the display 871 is 5062 cd / m². 2In other words, the contrast ratio of display 871 was black:white = 1:2,531,000. Due to its high contrast ratio, display 871 displayed deep blacks, making full use of the characteristics of OLED.

[0551] Furthermore, the OLEDs in the manufactured display device were produced using the SBS method, which involves separately coloring red (R), green (G), and blue (B). OLEDs produced using the SBS method are sometimes referred to as having an SBS structure. By producing the OLEDs using the SBS method, the OLEDs between pixels are not connected, thus reducing the power consumption of the display device.

[0552] Furthermore, the OLED in the fabricated display device is a metal-maskless (MML) structure, which is fabricated without using a metal mask. This MML structure was fabricated using photolithography. As a result, display 871 had a high aperture ratio of 60%.

[0553] Figure 54 is a chromaticity diagram showing the R, G, and B chromaticity of the fabricated display device when viewed from the front or at an oblique angle. Figure 54A shows the chromaticity of a display device fabricated using a white OLED and a color filter. The plots at points 892Ra, 892Ga, and 892Ba show the R, G, and B chromaticity when the display device is viewed from the front. The plots at points 892Rb, 892Gb, and 892Bb show the R, G, and B chromaticity when the display device is viewed at a 60° oblique angle. The plots at points 892Rc, 892Gc, and 892Bc show the R, G, and B chromaticity when the display device is viewed at a 60° oblique angle opposite to the above. Figure 54B shows the chromaticity of a display device fabricated using an SBS-type OLED. The plots at points 891Ra, 891Ga, and 891Ba show the R, G, and B chromaticity when the display device is viewed from the front. The plots at points 891Rb, 891Gb, and 891Bb show the R, G, and B chromaticity when the display device is viewed from a 60° angle. The plots at points 891Rc, 891Gc, and 891Bc show the R, G, and B chromaticity when the display device is viewed from the opposite 60° angle. By using an SBS-type OLED, the change in chromaticity due to viewing angle was dramatically improved compared to using a white OLED.

[0554] Based on the above display results, the display quality can be improved by a display device using a semiconductor device according to one aspect of the present invention.

[0555] Furthermore, electronic devices using the display devices shown in these embodiments (for example, xR devices such as VR devices or AR devices) may be fitted with thin clients or foveated rendering. By applying thin clients or foveated rendering, the power consumption of electronic devices using the display devices shown in these embodiments is reduced.

[0556] Table 2 shows the results of comparing the number of masks, off-current, and Vd breakdown voltage of the oxide semiconductor FETs in the fabricated display device with those of SiFETs.

[0557] [Table 2]

[0558] OSFETs do not require a doping process, so they can be manufactured with fewer masks than SiFETs. Therefore, the display devices shown in this embodiment can reduce manufacturing costs. Furthermore, the off-current of OSFETs is so low that it is difficult to measure with conventional electrical measurements, and is far lower than that of SiFETs. In addition, the Vd breakdown voltage of OSFETs is higher than that of SiFETs. Therefore, the display quality can be improved with the display devices shown in this embodiment.

[0559] The display device shown in this embodiment may also have a configuration in which SiFETs and OSFETs are stacked in multiple layers, as shown in Figure 32B, for example. For example, the functional circuits of the display device (peripheral drive circuits, CPU, GPU, and memory circuits, etc.) may be made of SiFETs, and the pixels of the display device may be made of OSFETs. By stacking layers of OSFETs on top of layers of SiFETs, miniaturization of the display device can be achieved. [Explanation of Symbols]

[0560] 51A: Pixel circuit, 51B: Pixel circuit, 61: Light-emitting element, 100A: Semiconductor device, 100B: Semiconductor device, 101: Wiring, 102: Wiring, 103: Wiring, 104: Wiring, M1: Transistor, M2: Transistor, M3: Transistor, M4: Transistor, M5: Transistor, M6: Transistor, M7: Transistor, C1: Capacitance, C2: Capacitance, C3: Capacitance, DL: Wiring, GLa: Wiring, GLB: Wiring, GLC: Wiring, GLD: Wiring, ND1: Node, ND2: Node, ND3: Node, ND4: Node, V0: Potential, V1: Potential, Va: Potential, Vc: Potential, Va1: Potential, Va2: Potential, T11: Period, T12: Period, T13: Period, T14: Period, T15: Period, T16: Period, T21: Period, T22: Period, T23: Period, T24: Period, T25: Period, T26: Period, F11: Frame, F12_1: Frame, F12_2: Frame, F14_1: Frame, F14_2: Frame, F21: Frame, F22_1: Frame, F22_2: Frame, F24_1: Frame, F24_2: Frame, S01: Step, S02: Step, S03: Step, S04: Step, S05: Step

Claims

1. comprising a first transistor, a switch, a display element, a first wiring, and a second wiring, The source of the first transistor is electrically connected to one terminal of the switch. The drain of the first transistor is electrically connected to the second wiring. The other terminal of the switch is electrically connected to the display element. A function that performs a first process of supplying a first potential to the source and the gate of the first transistor, A function that performs a second process of supplying the first potential to the source of the first transistor and supplying the potential of the first wiring to the gate of the first transistor, A function to perform a third process that causes the switch to enter a conductive state, It has a function to perform a fourth process that puts the switch into a non-conductive state, The fourth process and the third process are repeated. A method for driving a semiconductor device, After starting the fourth process, compare the potential of the first wiring with the first potential. As a result of the above comparison, if the potential of the first wiring and the first potential are the same, The first process is initiated, Before starting the third process, the first process is terminated. After the first process is completed, the second process is started. Before terminating the third process, perform the process to terminate the second process. If, as a result of the above comparison, the potential of the first wiring and the first potential are not at the same potential, The second process is initiated, Before completing the third process, perform the process to complete the second process. A method for driving semiconductor devices.

2. A device comprising a first transistor, a switch, a display element, a first wiring, and a second wiring, The source of the first transistor is electrically connected to one terminal of the switch. The drain of the first transistor is electrically connected to the second wiring. The other terminal of the switch is electrically connected to the display element. A function that performs a first processing which involves supplying a first potential to the source and gate of the first transistor, and supplying the same potential as the first potential to the first wiring, A function that performs a second process of supplying the first potential to the source of the first transistor and supplying the potential of the first wiring to the gate of the first transistor, A function to perform a third process that causes the switch to enter a conductive state, It has a function to perform a fourth process that puts the switch into a non-conductive state, The fourth process and the third process are repeated. A method for driving a semiconductor device, After starting the fourth process, start the first process. Before starting the third process, the first process is terminated. After the first process is completed, the second process is started. Before completing the third process, perform the process to complete the second process. A method for driving semiconductor devices.

3. comprising a first transistor, a switch, a display element, a first wiring, and a second wiring, The source of the first transistor is electrically connected to one terminal of the switch. The drain of the first transistor is electrically connected to the second wiring. The other terminal of the switch is electrically connected to the display element. A function that supplies a first potential to the source and gate of the first transistor and performs a first process that puts the first wiring into a floating state, A function that performs a second process of supplying the first potential to the source of the first transistor and supplying the potential of the first wiring to the gate of the first transistor, A function to perform a third process that causes the switch to enter a conductive state, It has a function to perform a fourth process that puts the switch into a non-conductive state, The fourth process and the third process are repeated. A method for driving a semiconductor device, After starting the fourth process, start the first process. Before starting the third process, the first process is terminated. After the first process is completed, the second process is started. Before completing the third process, perform the process to complete the second process. A method for driving semiconductor devices.

4. A device comprising a first transistor to a seventh transistor, a first capacitor to a third capacitor, a display element, and a first wiring to a sixth wiring, The third to seventh transistors have a function as switches. The first gate of the first transistor is electrically connected to the first wiring via the third transistor. The first gate of the first transistor is electrically connected to the source of the first transistor via the fourth transistor. The second gate of the first transistor is electrically connected to the fourth wiring via the fifth transistor. The source of the first transistor is electrically connected to the third wiring via the sixth transistor. The source of the first transistor is electrically connected to the drain of the second transistor. The drain of the first transistor is electrically connected to the second wiring. The gate of the second transistor is electrically connected to the fifth wiring via the seventh transistor. The source of the second transistor is electrically connected to the display element. The first capacitance is electrically connected between the first gate of the first transistor and the source of the first transistor. The second capacitance is electrically connected between the second gate of the first transistor and the source of the first transistor. The third capacitance is electrically connected between the gate of the second transistor and the source of the second transistor. The gate of the first transistor, the gate of the sixth transistor, and the gate of the seventh transistor are electrically connected to the sixth wiring. The function includes a first processing operation that supplies the potential of the third wiring to the source and gate of the first transistor, A function that performs a second process of supplying the potential of the third wiring to the source of the first transistor and supplying the potential of the first wiring to the gate of the first transistor, A function to perform a third process that causes the switch to enter a conductive state, It has a function to perform a fourth process that puts the switch into a non-conductive state, The fourth process and the third process are repeated. A method for driving a semiconductor device, After starting the fourth process, compare the potential of the first wiring and the potential of the third wiring. As a result of the above comparison, if the potential of the first wiring and the potential of the third wiring are the same, The first process is initiated, Before starting the third process, the first process is terminated. After the first process is completed, the second process is started. Before terminating the third process, perform the process to terminate the second process. If, as a result of the above comparison, the potential of the first wiring and the potential of the third wiring are not the same, The second process is initiated, Before completing the third process, perform the process to complete the second process. A method for driving semiconductor devices.

5. A device comprising a first transistor to a seventh transistor, a first capacitor to a third capacitor, a display element, and a first wiring to a sixth wiring, The third to seventh transistors have a function as switches. The first gate of the first transistor is electrically connected to the first wiring via the third transistor. The first gate of the first transistor is electrically connected to the source of the first transistor via the fourth transistor. The second gate of the first transistor is electrically connected to the fourth wiring via the fifth transistor. The source of the first transistor is electrically connected to the third wiring via the sixth transistor. The source of the first transistor is electrically connected to the drain of the second transistor. The drain of the first transistor is electrically connected to the second wiring. The gate of the second transistor is electrically connected to the fifth wiring via the seventh transistor. The source of the second transistor is electrically connected to the display element. The first capacitance is electrically connected between the first gate of the first transistor and the source of the first transistor. The second capacitance is electrically connected between the second gate of the first transistor and the source of the first transistor. The third capacitance is electrically connected between the gate of the second transistor and the source of the second transistor. The gate of the first transistor, the gate of the sixth transistor, and the gate of the seventh transistor are electrically connected to the sixth wiring. A function that performs a first process of supplying the potential of the third wiring to the source and gate of the first transistor, and supplying the same potential as the third wiring to the first wiring, A function that performs a second process of supplying the potential of the third wiring to the source of the first transistor and supplying the potential of the first wiring to the gate of the first transistor, A function to perform a third process that causes the switch to enter a conductive state, It has a function to perform a fourth process that puts the switch into a non-conductive state, The fourth process and the third process are repeated. A method for driving a semiconductor device, After starting the fourth process, start the first process. Before starting the third process, the first process is terminated. After the first process is completed, the second process is started. Before completing the third process, perform the process to complete the second process. A method for driving semiconductor devices.

6. A device comprising a first transistor to a seventh transistor, a first capacitor to a third capacitor, a display element, and a first wiring to a sixth wiring, The third to seventh transistors have a function as switches. The first gate of the first transistor is electrically connected to the first wiring via the third transistor. The first gate of the first transistor is electrically connected to the source of the first transistor via the fourth transistor. The second gate of the first transistor is electrically connected to the fourth wiring via the fifth transistor. The source of the first transistor is electrically connected to the third wiring via the sixth transistor. The source of the first transistor is electrically connected to the drain of the second transistor. The drain of the first transistor is electrically connected to the second wiring. The gate of the second transistor is electrically connected to the fifth wiring via the seventh transistor. The source of the second transistor is electrically connected to the display element. The first capacitance is electrically connected between the first gate of the first transistor and the source of the first transistor. The second capacitance is electrically connected between the second gate of the first transistor and the source of the first transistor. The third capacitance is electrically connected between the gate of the second transistor and the source of the second transistor. The gate of the first transistor, the gate of the sixth transistor, and the gate of the seventh transistor are electrically connected to the sixth wiring. The function includes supplying the potential of the third wiring to the source and gate of the first transistor, and performing a first process to put the first wiring into a floating state, A function that performs a second process of supplying the potential of the third wiring to the source of the first transistor and supplying the potential of the first wiring to the gate of the first transistor, A function to perform a third process that causes the switch to enter a conductive state, It has a function to perform a fourth process that puts the switch into a non-conductive state, The fourth process and the third process are repeated. A method for driving a semiconductor device, After starting the fourth process, start the first process. Before starting the third process, the first process is terminated. After the first process is completed, the second process is started. Before completing the third process, perform the process to complete the second process. A method for driving semiconductor devices.

7. In any one of claims 1 to 6, The first transistor includes a metal oxide in the semiconductor layer in which the channel is formed. A method for driving semiconductor devices.

8. In claim 7, The aforementioned metal oxide includes indium, A method for driving semiconductor devices.

9. In any one of claims 1 to 6, The display element has a tandem structure organic EL element. A method for driving semiconductor devices.