Semiconductor device and method for manufacturing the same
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- DENSO CORP
- Filing Date
- 2024-04-25
- Publication Date
- 2026-06-26
AI Technical Summary
Simultaneously forming contact holes of different depths in a semiconductor device can result in poor connections between electrodes and resistors, as the thinner resistor wiring may be penetrated, leading to connection failures.
The semiconductor device incorporates a stopper wiring and resistor wiring configuration, with a stopper layer on the resistor wiring, using the stopper layer as an etching stopper during dry etching and the stopper wiring as a stopper during reverse sputtering to prevent the resistor contact hole from penetrating the resistor, ensuring electrodes are connected securely.
This configuration prevents poor connections between electrodes and resistors by maintaining the integrity of the resistor wiring, allowing for simultaneous formation of contact holes of different depths without compromising the electrical connection.
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Abstract
Description
[Technical Field]
[0001] The present disclosure relates to a semiconductor device and a method for manufacturing the same. [Background technology]
[0002] For example, Patent Document 1 proposes a semiconductor device having a wiring layer disposed on a substrate. Specifically, the wiring layer in this semiconductor device is configured to have a portion where insulating films and wiring portions are alternately stacked. The wiring portion has connection wiring and a resistor configured by resistive wiring that is disposed on an insulating film different from the insulating film on which the connection wiring is disposed and is thinner than the connection wiring.
[0003] The wiring layer has formed therein contact holes exposing the connection wiring and contact holes exposing the resistance wiring, and electrodes connected to the connection wiring and resistance wiring are embedded in the contact holes. The contact holes exposing the connection wiring and the contact holes exposing the resistance wiring have different depths because the insulating film on which the connection wiring is disposed is different from the insulating film on which the resistance wiring is disposed. [Prior art documents] [Patent documents]
[0004] [Patent Document 1] Japanese Patent Application Publication No. 2019-186407 Summary of the Invention [Problem to be solved by the invention]
[0005] In the semiconductor device described above, the present inventors have considered simultaneously forming contact holes of different depths, one exposing a connection wiring and the other exposing a resistance wiring. However, if contact holes of different depths are simultaneously formed, the contact holes may penetrate the thin resistance wiring that constitutes the resistor, which may result in poor connection between the electrode disposed in the contact hole and the resistance wiring.
[0006] The present disclosure aims to provide a semiconductor device and a manufacturing method thereof that can suppress the occurrence of poor connections between electrodes placed in contact holes and resistors when contact holes of different depths are formed simultaneously. [Means for solving the problem]
[0007] According to one aspect of the present disclosure, a semiconductor device includes a substrate (10) having one surface (10a), and a wiring layer (20) disposed on the one surface and having a portion in which a plurality of insulating films (31-34) and a plurality of wiring portions (41-43) are alternately stacked, the wiring layer having a connection wiring (413) and a resistor (R) including a resistive wiring (422b) that is thinner than the connection wiring and is disposed on an insulating film different from the insulating film on which the connection wiring is disposed, and a connection wiring contact hole (75) exposing the connection wiring is formed, and an electrode (422b) connected to the connection wiring is disposed in the connection wiring contact hole. (85) is arranged, exposing the resistor, and resistor contact holes (73, 74) having a depth different from that of the contact holes for connection wiring are formed, and electrodes (83, 84) connected to the resistor are arranged in the resistor contact holes, the resistor is made of a conductive material and is composed of stopper wiring (422a, 423a, 424a) arranged in the part where the resistor contact holes are formed and resistance wiring arranged on the stopper wiring, and a stopper layer (52) made of a material different from the insulating film is arranged on the part of the resistor where the resistor contact holes are formed.
[0008] According to this, the portion of the resistor that connects to the electrode disposed in the resistor contact hole is configured by stacking stopper wiring and resistor wiring. A stopper layer is disposed on the resistor wiring. Therefore, even if the resistor contact hole and the connection wiring contact hole with different depths are formed simultaneously, the resistor contact hole can be prevented from penetrating the resistor. Therefore, poor connection between the resistor and the electrode disposed in the resistor contact hole can be prevented.
[0009] According to another aspect of the present disclosure, the method for manufacturing the semiconductor device described above includes preparing a substrate having one surface, repeatedly forming an insulating film and forming a wiring portion, and simultaneously forming a resistor contact hole and a connection wiring contact hole to form a wiring layer, and forming the wiring layer includes forming the connection wiring, arranging a stopper wiring and a resistor wiring on an insulating film different from the insulating film on which the connection wiring is arranged, and arranging a stopper layer on the resistor wiring, and when forming the resistor contact hole and the connection wiring contact hole, the stopper layer is used as an etching stopper layer, and first dry etching is performed to form the resistor contact hole reaching the stopper layer and the connection wiring contact hole reaching the connection wiring, second dry etching is performed to dig down the resistor contact hole so that the resistor contact hole penetrates the stopper layer and reaches the resistor wiring, and reverse sputtering is performed on the resistor wiring exposed from the resistor contact hole and the connection wiring exposed from the connection wiring contact hole.
[0010] According to this, the portion of the resistor that connects to the electrode disposed in the resistor contact hole is configured by stacking a stopper wiring and a resistor wiring. A stopper layer is disposed on the resistor wiring. Therefore, by using the stopper layer as an etching stopper when performing the first dry etching and the stopper wiring as a stopper when performing the reverse sputtering method, the resistor contact hole and the connection wiring contact hole of different depths can be formed simultaneously. This prevents poor connection between the resistor and the electrode disposed in the resistor contact hole.
[0011] The reference symbols in parentheses attached to each component indicate an example of the correspondence between the component and the specific components described in the embodiments described below. [Brief explanation of the drawings]
[0012] [Figure 1] 1 is a cross-sectional view of a semiconductor device according to a first embodiment. [Figure 2] FIG. 2 is a plan view showing the positional relationship between first to third wiring portions in FIG. [Figure 3] FIG. 2 is a diagram showing a circuit configuration of a resistor in the first embodiment. [Figure 4A] 2A to 2C are cross-sectional views showing a manufacturing process of the semiconductor device shown in FIG. [Figure 4B] 4B is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4A. [Figure 4C] FIG. 4C is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4B. [Figure 4D] 4D is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4C. [Figure 4E] FIG. 4E is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4D. [Figure 4F] FIG. 4F is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4E. [Figure 4G] FIG. 4F is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4F. [Figure 4H]FIG. 4C is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4G. [Figure 4I] FIG. 4C is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4H. [Figure 4J] 4I. FIG. 4I is a cross-sectional view showing a manufacturing process of the semiconductor device. [Figure 4K] 4J. FIG. 4C is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4J. [Figure 4L] FIG. 4K is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4K. [Figure 4M] 4B is a cross-sectional view showing the manufacturing process of the semiconductor device subsequent to FIG. 4L. [Figure 5] FIG. 10 is a cross-sectional view of a semiconductor device according to a second embodiment. [Figure 6] FIG. 10 is a circuit diagram of a resistor according to a second embodiment. DETAILED DESCRIPTION OF THE INVENTION
[0013] Hereinafter, embodiments of the present disclosure will be described with reference to the accompanying drawings. In the following embodiments, identical or equivalent parts will be denoted by the same reference numerals.
[0014] (First embodiment) A first embodiment will be described with reference to the drawings. The semiconductor device of this embodiment is suitable for use, for example, in a vehicle to drive various electronic components mounted on the vehicle. First, the configuration of the semiconductor device of this embodiment will be described with reference to Figures 1 and 2. Figure 1 is a cross-sectional view taken along line II in Figure 2.
[0015] The semiconductor device includes a substrate 10 made of a silicon substrate or the like. Although not shown, semiconductor elements such as diodes and transistors are formed on the substrate 10. A wiring layer 20 having a portion where first to fourth interlayer insulating films 31 to 34 and first to third wiring portions 41 to 43 are alternately stacked and having a resistor R and a capacitor C therein is disposed on one surface 10a of the substrate 10. Hereinafter, the region where the capacitor C is formed will be referred to as a capacitor region RC, the region where the resistor R is formed will be referred to as a resistor region RR, and the region different from the capacitor region RC and the resistor region RR will be referred to as a wiring region RW. Note that the wiring region RW is a region different from the capacitor region RC and the resistor region RR, and does not mean that a connection wiring 413 (described later) and the like are formed only in the wiring region RW.
[0016] Specifically, a first interlayer insulating film 31 is formed on one surface 10a of the substrate 10. The first interlayer insulating film 31 is made of a material such as a silicon oxide film (SiO2), a carbon-doped silicon oxide film (SiOC), a fluorine-doped silicon oxide film (SiOF), or a tetraethoxysilane film (TEOS). Second to fourth interlayer insulating films 32 to 34, which will be described later, are made of the same material as the first interlayer insulating film 31. However, the materials making up the first to fourth interlayer insulating films 31 to 34 can be changed as appropriate, and may be made of different materials.
[0017] A first wiring portion 41 is formed on the first interlayer insulating film 31. In this embodiment, the first wiring portion 41 is formed to include a lower electrode 411, a dummy wiring 412, and a connection wiring 413 of the capacitor C. More specifically, the lower electrode 411 is formed in a capacitor region RC, the dummy wiring 412 is formed in a resistor region RR, and the connection wiring 413 is formed in a wiring region RW.
[0018] In this embodiment, the connection wiring 413 is formed from the wiring region RW to the resistor region RR, and a portion of the connection wiring 413 faces a resistor R (described later) in the resistor region RR. In this embodiment, two dummy wirings 412 are formed, each facing a resistor R (described later). The first wiring portion 41 is made of a common electrode material, and in this embodiment, it is made of a laminate of titanium nitride (TiN), aluminum (Al), and titanium nitride. The third wiring portion 43 (described later) is made of the same material as the first wiring portion 41. However, the materials constituting the first wiring portion 41 and the third wiring portion 43 can be changed as appropriate, and may be made of a single layer of aluminum, for example. The first wiring portion 41 and the third wiring portion 43 may also be made of different materials.
[0019] A second interlayer insulating film 32 is formed on the first interlayer insulating film 31 so as to cover the first wiring portion 41. A hole 32a is formed in the second interlayer insulating film 32 to expose the lower electrode 411 of the first wiring portion 41. In this embodiment, the hole 32a has a tapered shape whose width narrows from the opening side toward the lower electrode 411 side.
[0020] A first oxidation resistant film 51 is disposed on the second interlayer insulating film 32. Specifically, the first oxidation resistant film 51 is formed on the second interlayer insulating film 32 around the hole 32a in the capacitor region RC and in the resistor region RR. The first oxidation resistant film 51 is made of, for example, a silicon nitride film (SiN) or a nitrogen-doped silicon carbide film (SiCN) that has low moisture permeability.
[0021] Furthermore, on the second interlayer insulating film 32, a capacitance film 60 is formed in the capacitor region RC and the resistor region RR. Specifically, the capacitance film 60 in the capacitor region RC is formed on the wall surface of the hole 32a and on the lower electrode 411 exposed from the hole 32a, and is also disposed on the first antioxidant film 51 disposed around the hole 32a. In this embodiment, the capacitance film 60 formed in the resistor region RR is disposed between a first stopper wiring 422a (described later) and the first antioxidant film 51, and between a second stopper wiring 423a (described later) and the first antioxidant film 51, and is thus divided into two portions. The capacitance film 60 is made of a silicon oxide film, a silicon nitride film, tantalum oxide (Ta2O5), or the like.
[0022] Then, a second wiring portion 42 is formed in the capacitor region RC and the resistor region RR on the second interlayer insulating film 32. The second wiring portion 42 of this embodiment is configured by stacking a lower-layer second wiring portion 42a and an upper-layer second wiring portion 42b.
[0023] The lower-layer second wiring portion 42a is formed in the capacitor region RC to include a first upper electrode 421a that is disposed opposite the lower electrode 411 and constitutes the capacitor C. The first upper electrode 421a is disposed on the capacitance film 60 and also around the hole 32a. The lower-layer second wiring portion 42a is formed in the resistor region RR to include a first stopper wiring 422a and a second stopper wiring 423a that are disposed on the capacitance film 60. More specifically, the first stopper wiring 422a and the second stopper wiring 423a are formed separately, with the first stopper wiring 422a disposed on one side of the separated capacitance film 60 and the second stopper wiring 423a disposed on the other side of the separated capacitance film 60. In this embodiment, the lower-layer second wiring portion 42a is made of titanium nitride. That is, the first stopper wiring 422a and the second stopper wiring 423a are made of a conductive material.
[0024] The upper-layer second wiring portion 42b has a second upper electrode 421b disposed on the first upper electrode 421a in the capacitor region RC. Therefore, the upper electrode 421 in the capacitor C of this embodiment is configured to include the first upper electrode 421a and the second upper electrode 421b. In this embodiment, the capacitor C has a so-called metal-insulator-metal (i.e., MIM) structure, including the lower electrode 411, the upper electrode 421, and the capacitive film 60 located between the lower electrode 411 and the upper electrode 421.
[0025] The upper-layer second wiring portion 42b is disposed on the first stopper wiring 422a and the second stopper wiring 423a in the resistance region RR, and is formed to include the resistance wiring 422b disposed between the first stopper wiring 422a and the second stopper wiring 423a. The upper-layer second wiring portion 42b is made of tantalum nitride (TaN), and is thinner than the lower-layer second wiring portion 42a, the first wiring portion 41, and the third wiring portion 43.
[0026] In the resistance region RR, the first stopper wiring 422a, the second stopper wiring 423a, and the resistance wiring 422b are each made of a conductive material, and therefore, as shown in Figure 3, the resistance R is made up of the first stopper wiring 422a, the second stopper wiring 423a, and the resistance wiring 422b.
[0027] Here, the properties of the resistor R in this embodiment will be described. As described above, the resistor R in this embodiment is configured to include the first stopper wiring 422a, the second stopper wiring 423a, and the resistive wiring 422b, each of which has a resistance temperature coefficient. For example, if the first stopper wiring 422a and the second stopper wiring 423a are configured from titanium nitride, the resistance temperature coefficient is 460 ppm / °C. If the resistive wiring 422b is configured from tantalum nitride, the resistance temperature coefficient is −60 ppm / °C. In other words, in this embodiment, the first stopper wiring 422a and the second stopper wiring 423a and the resistive wiring 422b have opposite signs of resistance temperature coefficients. Therefore, by configuring the first stopper wiring 422a and the second stopper wiring 423a from titanium nitride and configuring the resistive wiring 422b from tantalum nitride, as in this embodiment, the resistance temperature coefficient of the entire resistor R can be easily brought close to zero.
[0028] Furthermore, when the first stopper wiring 422a and the second stopper wiring 423a are made of titanium nitride and the resistive wiring 422b is made of tantalum nitride, the absolute value of the temperature coefficients of resistance of the first stopper wiring 422a and the second stopper wiring 423a is greater than that of the resistive wiring 422b. For this reason, in this embodiment, the resistive wiring 422b is arranged so that its area is greater than that of the first stopper wiring 422a and the second stopper wiring 423a so that the overall temperature coefficient of resistance of the resistor R approaches 0 ppm / °C. In this embodiment, the first stopper wiring 422a and the second stopper wiring 423a are arranged separately, as described above. The resistance wiring 422b is arranged on the first stopper wiring 422a, on the second stopper wiring 423a, and between the first stopper wiring 422a and the second stopper wiring 423a, so that the area of the resistance wiring 422b is larger than that of the first stopper wiring 422a and the second stopper wiring 423a.
[0029] In this embodiment, the outer edge of the first upper electrode 421a, the first stopper wiring 422a, and the second stopper wiring 423a are respectively disposed on the first antioxidant film 51 and the capacitance film 60 on the second interlayer insulating film 32. Therefore, the outer edge of the first upper electrode 421a, the first stopper wiring 422a, and the second stopper wiring 423a are located on the same plane. Similarly, the outer edge of the second upper electrode 421b and the resistance wiring 422b are located on the same plane. In this embodiment, by arranging parts made of the same material on the same plane and allowing them to be processed in the same process, the manufacturing process can be simplified.
[0030] Furthermore, the outer edge portions of the first upper electrode 421a and the second upper electrode 421b are aligned in the stacking direction (hereinafter simply referred to as the stacking direction) of the first to fourth interlayer insulating films 31 to 34 and the first to third wiring portions 41 to 43. In other words, the first upper electrode 421a and the second upper electrode 421b are formed so that the end faces of the outer edge portions are positioned on the same plane along the stacking direction. This reduces the parasitic capacitance formed between the first upper electrode 421a and the lower electrode 411, for example, compared to when the first upper electrode 421a protrudes from the second upper electrode 421b. Note that the stacking direction can also be referred to as the normal direction to the surface 10a of the substrate 10.
[0031] On the upper-layer second wiring portion 42b, in the capacitor region RC and the resistor region RR, a second oxidation resistant film 52 and an internal insulating film 53 are disposed in this order from the upper-layer second wiring portion 42b side. Like the first oxidation resistant film 51, the second oxidation resistant film 52 is made of a moisture-permeable silicon nitride film, a nitrogen-doped silicon carbide film, or the like. The second oxidation resistant film 52 also functions as an etching stopper, is made of a different material from the second to fourth interlayer insulating films 32 to 34, and corresponds to a stopper layer. The internal insulating film 53, which will be described in detail later, is used as a mask when the first oxidation resistant film 51, the capacitance film 60, the second wiring portion 42, and the second oxidation resistant film 52 are collectively patterned, and may not be provided.
[0032] A third interlayer insulating film 33 is disposed on the second interlayer insulating film 32 so as to cover the second wiring portion 42 and the like, and a fourth interlayer insulating film 34 is disposed on the third interlayer insulating film 33. The fourth interlayer insulating film 34 functions as a cap insulating film, and seals off any foreign matter that is exposed from the surface of the third interlayer insulating film 33 opposite to the substrate 10 side.
[0033] In the capacitor region RC, an upper electrode contact hole 71 is formed, which penetrates the fourth interlayer insulating film 34, the third interlayer insulating film 33, the internal insulating film 53, and the second antioxidant film 52 to reach the upper electrode 421. In addition, in the capacitor region RC, a lower electrode contact hole 72 is formed, which penetrates the fourth interlayer insulating film 34, the third interlayer insulating film 33, and the second interlayer insulating film 32 to expose the lower electrode 411.
[0034] In the resistor region RR, a first resistor contact hole 73 is formed, penetrating the fourth interlayer insulating film 34, the third interlayer insulating film 33, the internal insulating film 53, and the second antioxidant film 52 to reach a portion of the resistor wiring 422b located above the first stopper wiring 422a. In the resistor region RR, a second resistor contact hole 74 is formed, penetrating the fourth interlayer insulating film 34, the third interlayer insulating film 33, the internal insulating film 53, and the second antioxidant film 52 to reach a portion of the resistor wiring 422b located above the second stopper wiring 423a. More specifically, in this embodiment, the first resistor contact hole 73 is formed to penetrate the resistor wiring 422b to reach the first stopper wiring 422a. The second resistor contact hole 74 is formed to penetrate the resistor wiring 422b to reach the second stopper wiring 423a.
[0035] In the wiring region RW, a contact hole 75 for connection wiring is formed, which penetrates the fourth interlayer insulating film 34, the third interlayer insulating film 33, and the second interlayer insulating film 32 and reaches the connection wiring 413.
[0036] In this embodiment, the lower electrode contact hole 72 and the connection wiring contact hole 75 have the same depth. Also, the first resistor contact hole 73 and the second resistor contact hole 74 have the same depth. However, the lower electrode contact hole 72 and the connection wiring contact hole 75, the first resistor contact hole 73 and the second resistor contact hole 74, and the upper electrode contact hole 71 have different depths. Also, in this embodiment, the first resistor contact hole 73 and the second resistor contact hole 74 are shallower than the other contact holes 71, 72, and 75.
[0037] A first electrode 81 is disposed in the upper electrode contact hole 71, and a second electrode 82 is disposed in the lower electrode contact hole 72. A third electrode 83 is disposed in the first resistor contact hole 73, and a fourth electrode 84 is disposed in the second resistor contact hole 74. A fifth electrode 85 is disposed in the connection wiring contact hole 75. In this embodiment, the first to fifth electrodes 81 to 85 are configured by first to fifth buried electrodes 81b to 85b disposed with first to fifth barrier metal films 81a to 85a interposed therebetween. The first to fifth barrier metal films 81a to 85a are configured, for example, by stacked films of titanium and titanium nitride, and the first to fifth buried electrodes 81b to 85b are configured by tungsten plugs. In this way, by configuring the first to fifth electrodes 81 to 85 to include tungsten plugs, the size of the opening of each contact hole 71 to 75 can be made smaller than when the first to fifth electrodes 81 are configured by embedding the third wiring portion 43 described below, thereby improving design freedom.
[0038] A third wiring portion 43 is formed on the fourth interlayer insulating film 34. Specifically, the third wiring portion 43 is formed to include an upper electrode wiring portion 431 and a lower electrode wiring portion 432 arranged in the capacitor region RC, a first resistor wiring portion 433, a second resistor wiring portion 434, and a dummy wiring portion 435 arranged in the resistor region RR, and a connection wiring portion 436 arranged in the wiring region RW.
[0039] The upper electrode wiring portion 431 formed in the capacitor region RC is connected to the upper electrode 421 via the first electrode 81, and the lower electrode wiring portion 432 is connected to the lower electrode 411 via the second electrode 82. The first resistor wiring portion 433 formed in the resistor region RR is connected to a portion of the resistor R on the first stopper wiring 422a side via the third electrode 83. The second resistor wiring portion 434 formed in the resistor region RR is connected to a portion of the resistor R on the second stopper wiring 423a side via the fourth electrode 84. In this embodiment, the dummy wiring portion 435 is disposed between the first resistor wiring portion 433 and the second resistor wiring portion 434, and is disposed so as to face a portion of the resistor wiring 422b located between the first stopper wiring 422a and the second stopper wiring 423a. The dummy wiring portion 435 is intended to prevent moisture from above the fourth interlayer insulating film 34 from penetrating into the wiring layer 20. The connection wiring wiring portion 436 formed in the wiring region RW is connected to the connection wiring 413 via the fifth electrode 85 .
[0040] The above is the configuration of the semiconductor device in this embodiment. The first to third wiring portions 41 to 43 are only a part of the configuration of the semiconductor device, and are also formed appropriately in a cross section different from that shown in Fig. 1. The first to third wiring portions 41 to 43 formed in a cross section different from that shown in Fig. 1 are electrically connected through connection vias formed appropriately in the first to fourth interlayer insulating films 31 to 34.
[0041] Next, a method for manufacturing the semiconductor device will be described with reference to FIGS. 4A to 4M.
[0042] First, as shown in FIG. 4A , a substrate 10 having semiconductor elements formed thereon is prepared, and a first interlayer insulating film 31 is disposed on the substrate 10 by, for example, a CVD (short for chemical vapor deposition) method. Then, a metal layer having titanium nitride, aluminum, and titanium nitride stacked thereon is formed by, for example, a sputtering method on the first interlayer insulating film 31. A photoresist mask (not shown) is then placed on the metal layer, and dry etching is performed to form a first wiring portion 41 having a lower electrode 411, dummy wiring 412, and connection wiring 413. Then, a second interlayer insulating film 32 is formed on the first interlayer insulating film 31 by, for example, a CVD method so as to cover the first wiring portion 41. Next, the surface of the second interlayer insulating film 32 opposite the substrate 10 side is planarized by, for example, a CMP (short for chemical mechanical polishing) method, and then a first oxidation prevention film 51 is disposed on the second interlayer insulating film 32 by, for example, a CVD method.
[0043] 4B, photoresist 100 is placed on the first antioxidant film 51 and patterned, and dry etching is performed using the photoresist 100 as a mask to form holes 32a that expose the lower electrodes 411. Thereafter, the photoresist 100 is removed by ashing or the like.
[0044] 4C, the capacitive film 60 and the lower-layer second wiring portion 42a are sequentially disposed. The capacitive film 60 is disposed by, for example, a CVD method, and the lower-layer second wiring portion 42a is disposed by a sputtering method or the like.
[0045] 4D, a photoresist 110 is disposed on the first oxidation resistant film 51 and patterned. Then, dry etching is performed using the photoresist 110 as a mask to simultaneously pattern the lower-layer second wiring portion 42a and the first oxidation resistant film 51, thereby forming a first upper electrode 421a, a first stopper wiring 422a, and a second stopper wiring 423a.
[0046] In this process, the lower-layer second wiring portion 42a is patterned to form the first upper electrode 421a, the first stopper wiring 422a, and the second stopper wiring 423a, but the outer edge portions are patterned to be slightly larger. Specifically, in this process, the outer edge portion of the first upper electrode 421a is made slightly larger in the surface direction. The first stopper wiring 422a is made slightly larger in the surface direction on the side opposite the second stopper wiring 423a. The second stopper wiring 423a is made slightly larger in the surface direction on the side opposite the first stopper wiring 422a.
[0047] 4E, the upper-layer second wiring portion 42b, the second oxidation resistant film 52, and the internal insulating film 53 are sequentially arranged. The upper-layer second wiring portion 42b is arranged by a sputtering method or the like, and the second oxidation resistant film 52 and the internal insulating film 53 are arranged by a CVD method or the like.
[0048] 4F, photoresist 120 is disposed on the internal insulating film 53 and patterned, and then dry etching is performed using the photoresist 120 as a mask to pattern the internal insulating film 53. Specifically, the internal insulating film 53 is patterned so that the internal insulating film 53 remains only on the portion that will ultimately form the resistor R and the portion that will ultimately form the upper electrode 421.
[0049] Note that the connection wiring 413 in this embodiment extends to the resistance region RR and has a portion facing the portion that becomes the resistance R. In this case, when exposure is performed to pattern the photoresist 120, reflection may differ between the portion where the connection wiring 413 is arranged and the portion where the connection wiring 413 is not arranged, which may reduce the accuracy of patterning. For this reason, in this embodiment, dummy wiring 412 is arranged in the resistance region RR to suppress the difference in reflection between the portion where the connection wiring 413 is arranged and the portion where the connection wiring 413 is not arranged in the region below the portion that becomes the resistance R.
[0050] 4G, after the photoresist 120 is removed by ashing or the like, dry etching is performed using the internal insulating film 53 as a mask (i.e., a hard mask) to simultaneously pattern the second oxidation preventing film 52, the second wiring portion 42, the capacitance film 60, and the first oxidation preventing film 51. As a result, a capacitor C is formed having the lower electrode 411, the upper electrode 421, and the capacitance film 60, and a resistor R is formed having the first stopper wiring 422a, the second stopper wiring 423a, and the resistance wiring 422b.
[0051] Next, as shown in FIG. 4H , a third interlayer insulating film 33 is disposed by a CVD method or the like, and the surface of the third interlayer insulating film 33 opposite the substrate 10 side is planarized by a CMP method or the like. During this process, metallic foreign matter or the like generated in each process may be exposed from the surface of the third interlayer insulating film 33 opposite the substrate 10 side, which may cause a short circuit or the like. For this reason, in this embodiment, a fourth interlayer insulating film 34 serving as a cap insulating film is further disposed on the third interlayer insulating film 33 by a CVD method or the like.
[0052] 4I and 4J, contact holes 71 for the upper electrode, contact holes 72 for the lower electrode, contact holes 73 for the first resistor, contact holes 74 for the second resistor, and contact holes 75 for the connecting wiring are formed simultaneously. In other words, contact holes of different depths are formed simultaneously.
[0053] In this embodiment, first, as shown in FIG. 4I, photoresist 130 is disposed on the fourth interlayer insulating film 34 and patterned. Then, a first dry etching process is performed using the photoresist 130 as a mask to form an upper electrode contact hole 71, a lower electrode contact hole 72, a first resistor contact hole 73, a second resistor contact hole 74, and a connection wiring contact hole 75. Specifically, the first dry etching process is performed by adjusting the selectivity so that the second oxidation preventing film 52 serves as an etching stopper. As a result, the upper electrode contact hole 71, the first resistor contact hole 73, and the second resistor contact hole 74 are formed to reach the second oxidation preventing film 52. The lower electrode contact hole 72 and the connection wiring contact hole 75 are each formed to reach the first wiring portion 41.
[0054] 4J, the photoresist 130 is removed by ashing or the like. Then, a second dry etching is performed by adjusting the selectivity to penetrate the second anti-oxidation film 52, so that the upper electrode contact hole 71, the first resistor contact hole 73, and the second resistor contact hole 74 reach the upper-layer second wiring portion 42b. At this time, the lower electrode contact hole 72 and the connection wiring contact hole 75 are also slightly removed, but because the lower electrode 411 and the connection wiring 413 are made of thick metal, there is no particular problem even if they are slightly removed by the second dry etching.
[0055] When removing the photoresist 130 or between steps, the second upper electrode 421b exposed from the upper electrode contact hole 71 and the lower electrode 411 exposed from the lower electrode contact hole 72 may be oxidized to form a natural oxide film. Also, the resistor wiring 422b exposed from the first resistor contact hole 73 and the second resistor contact hole 74 and the connection wiring 413 exposed from the connection wiring contact hole 75 may be oxidized to form a natural oxide film. For this reason, in this embodiment, a reverse sputtering method is performed to perform a step of removing the natural oxide film.
[0056] Note that, when performing the second dry etching or reverse sputtering, the first resistor contact hole 73 and the second resistor contact hole 74 may penetrate the resistor wiring 422b because the resistor wiring 422b is thin. For this reason, in this embodiment, the first stopper wiring 422a and the second stopper wiring 423a are arranged below the resistor wiring 422b so that the first stopper wiring 422a and the second stopper wiring 423a act as stoppers even if the first resistor contact hole 73 and the second resistor contact hole 74 penetrate the resistor wiring 422b. For this reason, when the third electrode 83 and the fourth electrode 84 are arranged as described below, it is possible to prevent the resistor R from being connected to the third electrode 83 and the fourth electrode 84 only through the side surfaces of the first resistor contact hole 73 and the second resistor contact hole 74, thereby preventing poor connection.
[0057] In this embodiment, the upper electrode contact hole 71, the lower electrode contact hole 72, the first resistor contact hole 73, the second resistor contact hole 74, and the connection wiring contact hole 75 are formed simultaneously in this manner.
[0058] Next, as shown in FIG. 4K, in a vacuum state during reverse sputtering, titanium and titanium nitride are deposited in order by sputtering or the like to form first to fifth barrier metal films 81a to 85a. Thereafter, as shown in FIG. 4L, the vacuum state is released, and tungsten is deposited by CVD or the like to form first to fifth buried electrodes 81b to 85b that fill the upper electrode contact hole 71, the lower electrode contact hole 72, the first resistor contact hole 73, the second resistor contact hole 74, and the connection wiring contact hole 75, thereby forming the first to fifth electrodes 81b to 85b. Subsequently, as shown in FIG. 4M, the material constituting the first to fifth barrier metal films 81a to 85a and the material constituting the first to fifth buried electrodes 81b to 85b that are disposed on the fourth interlayer insulating film 34 is removed by CMP or the like to expose the fourth interlayer insulating film 34.
[0059] Thereafter, although not particularly shown, the third wiring portion 43 is disposed on the fourth interlayer insulating film 34 by a sputtering method or the like. Then, the third wiring portion 43 is patterned to form an upper electrode wiring portion 431, a lower electrode wiring portion 432, a first resistor wiring portion 433, a second resistor wiring portion 434, a dummy wiring portion 435, and a connection wiring portion 436, thereby manufacturing the semiconductor device shown in FIG.
[0060] According to the present embodiment described above, the portion of the resistor R connected to the third electrode 83 arranged in the first resistor contact hole 73 is configured by laminating the first stopper wiring 422a and the resistor wiring 422b. The portion of the resistor R connected to the fourth electrode 84 arranged in the second resistor contact hole 74 is configured by laminating the second stopper wiring 423a and the resistor wiring 422b. The second oxidation prevention film 52 is disposed on the resistor wiring 422b. Therefore, even if the first resistor contact hole 73 and the second resistor contact hole 74 are formed simultaneously with the upper electrode contact hole 71, the lower electrode contact hole 72, and the connection wiring contact hole 75, which have different depths, the first resistor contact hole 73 and the second resistor contact hole 74 can be prevented from penetrating the resistor R. This can prevent poor connection between the resistor R and the third electrode 83 arranged in the first resistor contact hole 73 and the fourth electrode 84 arranged in the second resistor contact hole 74.
[0061] (1) In this embodiment, the resistor R is configured by stacking the first stopper wiring 422a and the second stopper wiring 423a, which have temperature coefficients of resistance with opposite signs, and the resistive wiring 422b. Therefore, for example, compared to when the resistor R is configured only by the resistive wiring 422b, the temperature coefficient of resistance of the resistor R can be made closer to 0.
[0062] (2) In this embodiment, the absolute values of the resistance temperature coefficients of the first stopper wiring 422a and the second stopper wiring 423a are set to be larger than the resistance temperature coefficient of the resistive wiring 422b. Therefore, in this embodiment, the resistive wiring 422b is arranged so that its area is larger than the areas of the first stopper wiring 422a and the second stopper wiring 423a. This makes it easier to bring the resistance temperature coefficient of the resistor R closer to 0.
[0063] (3) In this embodiment, the wiring layer 20 is configured to include a capacitor C. The upper electrode 421 of the capacitor C is configured by stacking a first upper electrode 421a made of the same material as the first stopper wiring 422a and the second stopper wiring 423a, and a second upper electrode 421b made of the same material as the resistor wiring 422b. Therefore, the material of the resistor R can be the same as the material of the upper electrode 421 of the capacitor C.
[0064] (4) In this embodiment, the outer edge of the first upper electrode 421a, the first stopper wiring 422a, and the second stopper wiring 423a are located on the same plane. Similarly, the outer edge of the second upper electrode 421b and the resistance wiring 422b are located on the same plane. Therefore, the resistance R and the upper electrode 421 can be processed in the same process, which simplifies the manufacturing process.
[0065] (5) In this embodiment, the outer edges of the first upper electrode 421a and the second upper electrode 421b are aligned in the stacking direction, which reduces the parasitic capacitance between the first upper electrode 421a and the lower electrode 411 compared to when the first upper electrode 421a protrudes from the second upper electrode 421b.
[0066] (6) In this embodiment, the first resistor contact hole 73 and the second resistor contact hole 74 are shallower than the upper electrode contact hole 71, the lower electrode contact hole 72, and the connecting wiring contact hole 75. This makes it easier to form the capacitor C in which the hole 32a is formed and the upper electrode 421 is disposed in the hole 32a as in this embodiment.
[0067] (Second embodiment) A second embodiment will be described. This embodiment is different from the first embodiment in that the configuration of the resistor R is changed. As the rest is the same as the first embodiment, a description thereof will be omitted here.
[0068] 5, in this embodiment, the first stopper wiring 422a and the second stopper wiring 423a are combined into one stopper wiring 424a. The resistive wiring 422b is disposed over the entire stopper wiring 424a. The resistive wiring 422b is disposed over the entire stopper wiring 424a, and has the same area as the resistive wiring 422b.
[0069] 6, in such a semiconductor device, the resistor R is configured by connecting the stopper wiring 424a and the resistance wiring 422b in parallel. Compared to the first embodiment, the stopper wiring 424a is not separated from the resistor R, so that the resistance value of the resistor R can be easily reduced.
[0070] Such a semiconductor device is manufactured by forming one stopper wiring 424a when patterning the second wiring portion 42 in the step of FIG. 4D.
[0071] (1) In this embodiment, the resistive wiring 422b is disposed over the entire stopper wiring 424a and has the same area as the stopper wiring 424a. This makes it easier to reduce the resistance value of the resistor R.
[0072] According to the present embodiment described above, the portion of the resistor R connected to the third electrode 83 arranged in the first resistor contact hole 73 is configured by laminating a first stopper wiring 422a and a resistor wiring 422b. The portion of the resistor R connected to the fourth electrode 84 arranged in the second resistor contact hole 74 is configured by laminating a second stopper wiring 423a and a resistor wiring 422b. The second antioxidant film 52 is arranged on the resistor wiring 422b. Therefore, the same effects as those of the first embodiment can be obtained.
[0073] (Other embodiments) Although the present disclosure has been described with reference to the embodiments, it is understood that the present disclosure is not limited to the embodiments or structures. The present disclosure also encompasses various modifications and modifications within the scope of equivalents. In addition, various combinations and forms, as well as other combinations and forms including only one element, more than one element, or less than one element, are also within the scope and spirit of the present disclosure.
[0074] For example, in each of the above embodiments, the capacitor C may not be provided in the wiring layer 20. Furthermore, in each of the above embodiments, when the capacitor C is provided in the wiring layer 20, the upper electrode 421 of the capacitor C and the resistor R may not be made of the same material. Furthermore, when the capacitor C is provided in the wiring layer 20, the outer edge of the upper electrode 421 of the capacitor C and the resistor R may not be formed on the same plane. Furthermore, when the capacitor C is provided in the wiring layer 20, the outer edge faces of the first upper electrode 421a and the second upper electrode 421b of the capacitor C along the stacking direction may not be aligned.
[0075] Furthermore, in each of the above embodiments, the first resistor contact hole 73 and the second resistor contact hole 74 may be deeper than the upper electrode contact hole 71, the lower electrode contact hole 72, and the connection wiring contact hole 75.
[0076] In each of the above embodiments, the dummy wiring 412 and the dummy wiring portion 435 arranged in the resistance region RR may be configured as connection wiring that is connected to other components or the like, depending on how the wiring portion is routed.
[0077] Furthermore, in each of the above embodiments, the materials constituting the lower-layer second wiring portion 42a and the upper-layer second wiring portion 42b can be changed as appropriate. For example, the lower-layer second wiring portion 42a may be made of chromium silicon (CrSi) or the like.
[0078] In the above embodiments, the semiconductor device has been described as having one resistor R and one capacitor C, but the number of resistors R and capacitors C can be changed as appropriate. For example, when a plurality of resistors R are provided, a pair of resistors may be configured. When configuring a pair of resistors, the accuracy of the pair of resistors can be improved by making the configuration of the portion located closer to the substrate 10 than each resistor R the same and the configuration of the portion located opposite the substrate 10 than each resistor R the same.
[0079] [Disclosure of the Invention] The present disclosure described above can be understood from the following viewpoints, for example. [First viewpoint] A semiconductor device, a substrate (10) having one surface (10a); a wiring layer (20) disposed on the one surface and having a portion in which a plurality of insulating films (31-34) and a plurality of wiring portions (41-43) are alternately stacked, the wiring layer has a connection wiring (413) and a resistor (R) including a resistive wiring (422b) that is thinner than the connection wiring and is arranged on an insulating film different from the insulating film on which the connection wiring is arranged, a connection wiring contact hole (75) that exposes the connection wiring is formed, and an electrode (85) that is connected to the connection wiring is arranged in the connection wiring contact hole, resistance contact holes (73, 74) that expose the resistor and have a depth different from that of the connection wiring contact hole are formed, and electrodes (83, 84) that are connected to the resistor are arranged in the resistance contact hole, the resistor is made of a conductive material and includes stopper wiring (422a, 423a, 424a) arranged in a portion where the resistor contact hole is to be formed, and the resistor wiring arranged on the stopper wiring, The semiconductor device further comprises a stopper layer (52) made of a material different from that of the insulating film, disposed on the portion of the resistor where the resistor contact hole is formed. [Second viewpoint] The semiconductor device according to a first aspect, wherein the resistive wiring and the stopper wiring are made of materials having temperature coefficients of resistance with opposite signs. [Third Perspective] The resistor is disposed on an oxidation prevention film (51), the resistive wiring and the stopper wiring are made of a material whose absolute value of the temperature coefficient of resistance of the resistive wiring is smaller than that of the stopper wiring, the stopper wiring has a first stopper wiring (422a) and a second stopper wiring (423a) that are arranged separately, A semiconductor device according to a second aspect, wherein the resistance wiring is arranged on the first stopper wiring and the second stopper wiring, and is arranged on the anti-oxidation film between the first stopper wiring and the second stopper wiring, and has a larger area than the stopper wiring. [Fourth viewpoint] The stopper wiring is formed in a continuous manner, The semiconductor device according to a second aspect, wherein the resistive wiring is formed over the entire stopper wiring. [Fifth viewpoint] the wiring layer has a capacitor (C) having a capacitance film (60) between the upper electrode (421) and the wiring portion on the substrate side as a lower electrode (411) and the wiring portion on the opposite side to the substrate side as an upper electrode (421) in two of the wiring portions that are opposed to each other in a stacking direction of the insulating film and the wiring portions among the plurality of wiring portions; The semiconductor device according to any one of the first to fourth aspects, wherein the upper electrode is formed by stacking a first upper electrode (421a) made of the same material as the stopper wiring and a second upper electrode (421b) made of the same material as the resistance wiring. [Sixth viewpoint] the stopper wiring and the outer edge of the first upper electrode are located on the same plane; the resistive wiring and the outer edge of the second upper electrode are located on the same plane; The semiconductor device according to a fifth aspect, wherein the stopper layer is disposed on the upper electrode. [Seventh viewpoint] The semiconductor device according to the fifth or sixth aspect, wherein the first upper electrode and the second upper electrode have outer edge portions aligned in the stacking direction. [Eighth viewpoint] The semiconductor device according to any one of fifth to seventh aspects, wherein the lower electrode is disposed on the insulating film different from the insulating film on which the resistor is disposed. [Ninth viewpoint] The semiconductor device according to any one of the first to eighth aspects, wherein the resistor contact holes are shallower in depth than the connection wiring contact holes. [10th viewpoint] a substrate (10) having one surface (10a); a wiring layer (20) disposed on the one surface and having a portion in which a plurality of insulating films (31-34) and a plurality of wiring portions (41-43) are alternately stacked, the wiring layer has a connection wiring (413) and a resistor (R) including a resistive wiring (422b) that is thinner than the connection wiring and is arranged on an insulating film different from the insulating film on which the connection wiring is arranged, a connection wiring contact hole (75) that exposes the connection wiring is formed, and an electrode (85) that is connected to the connection wiring is arranged in the connection wiring contact hole, resistance contact holes (73, 74) that expose the resistor and have a depth different from that of the connection wiring contact hole are formed, and electrodes (83, 84) that are connected to the resistor are arranged in the resistance contact hole, the resistor is made of a conductive material and includes stopper wiring (422a, 423a, 424a) arranged in a portion where the resistor contact hole is to be formed, and the resistor wiring arranged on the stopper wiring, A method of manufacturing a semiconductor device, wherein a stopper layer (52) made of a material different from that of the insulating film is disposed on a portion of the resistor where the resistor contact hole is formed, providing the substrate having the one surface; forming the insulating film and the wiring portion repeatedly, and simultaneously forming the resistor contact holes and the connection wiring contact holes to form the wiring layer; By forming the wiring layer, forming the connection wiring, arranging the stopper wiring and the resistance wiring on the insulating film different from the insulating film on which the connection wiring is arranged, and arranging the stopper layer on the resistance wiring; A method for manufacturing a semiconductor device, comprising the steps of: performing a first dry etching process using the stopper layer as an etching stopper layer when forming the resistor contact holes and the connection wiring contact holes, forming the resistor contact holes that reach the stopper layer and the connection wiring contact holes that reach the connection wiring; performing a second dry etching process to dig down the resistor contact holes so that the resistor contact holes penetrate the stopper layer and reach the resistor wiring; and performing a reverse sputtering process on the resistor wiring exposed from the resistor contact holes and the connection wiring exposed from the connection wiring contact holes. [Explanation of symbols]
[0080] 10 Substrate 10a one side 20 wiring layer 31-34 Insulating film 41~43 Wiring section 73, 74 Resistor contact holes 75 Contact holes for connecting wiring 83~85 electrode 413 Connection wiring 422a, 423a Stopper wiring 422b Resistance wiring
Claims
1. A semiconductor device, A substrate (10) having one surface (10a), The wiring layer (20) is arranged on the aforementioned surface and has portions in which a plurality of insulating films (31-34) and a plurality of wiring portions (41-43) are alternately stacked, The wiring layer includes a connection wiring (413) and a resistor (R) comprising a resistance wiring (422b) which is thinner than the connection wiring and arranged on an insulating film different from the insulating film on which the connection wiring is arranged, and a connection wiring contact hole (75) is formed to expose the connection wiring and an electrode (85) connected to the connection wiring is arranged in the connection wiring contact hole, and a resistance contact hole (73, 74) is formed to expose the resistor and which has a different depth from the connection wiring contact hole and an electrode (83, 84) connected to the resistor is arranged in the resistance contact hole. The resistor is made of a conductive material and comprises stopper wiring (422a, 423a, 424a) arranged in the portion where the resistor contact hole is formed, and the resistor wiring arranged on the stopper wiring. A stopper layer (52) made of a different material from the insulating film is placed on the portion of the resistor in which the contact hole for the resistor is formed. A semiconductor device in which the resistor wiring and the stopper wiring are made of materials having opposite signs in their temperature coefficient of resistance.
2. The resistor is placed on the antioxidant film (51), The resistive wiring and the stopper wiring are made of a material in which the absolute value of the temperature coefficient of resistance of the resistive wiring is smaller than the absolute value of the temperature coefficient of resistance of the stopper wiring. The stopper wiring comprises a first stopper wiring (422a) and a second stopper wiring (423a) that are arranged separately. The semiconductor device according to claim 1, wherein the resistor wiring is arranged on the first stopper wiring and the second stopper wiring, and is arranged on the oxidation prevention film between the first stopper wiring and the second stopper wiring, and has a larger area than the stopper wiring.
3. The stopper wiring is formed by being connected, The semiconductor device according to claim 1, wherein the resistor wiring is formed over the entire stopper wiring.
4. A semiconductor device, A substrate (10) having one surface (10a), The wiring layer (20) is arranged on the aforementioned surface and has portions in which a plurality of insulating films (31-34) and a plurality of wiring portions (41-43) are alternately stacked, The wiring layer includes a connection wiring (413) and a resistor (R) comprising a resistance wiring (422b) which is thinner than the connection wiring and arranged on an insulating film different from the insulating film on which the connection wiring is arranged, and a connection wiring contact hole (75) is formed to expose the connection wiring and an electrode (85) connected to the connection wiring is arranged in the connection wiring contact hole, and a resistance contact hole (73, 74) is formed to expose the resistor and which has a different depth from the connection wiring contact hole and an electrode (83, 84) connected to the resistor is arranged in the resistance contact hole. The resistor is made of a conductive material and comprises stopper wiring (422a, 423a, 424a) arranged in the portion where the resistor contact hole is formed, and the resistor wiring arranged on the stopper wiring. A stopper layer (52) made of a different material from the insulating film is placed on the portion of the resistor in which the contact hole for the resistor is formed. The wiring layer has, in two of the plurality of wiring portions that are opposite each other in the stacking direction between the insulating film and the wiring portion, the wiring portion on the substrate side is designated as the lower electrode (411) and the wiring portion on the opposite side from the substrate side is designated as the upper electrode (421), and a capacitor (C) having a capacitive film (60) is provided between the upper electrode and the lower electrode. The semiconductor device is configured such that the upper electrode is formed by stacking a first upper electrode (421a) made of the same material as the stopper wiring and a second upper electrode (421b) made of the same material as the resistance wiring.
5. The stopper wiring and the outer edge end of the first upper electrode are located on the same plane. The resistor wiring and the outer edge of the second upper electrode are located on the same plane. The semiconductor device according to claim 4, wherein the stopper layer is disposed on the upper electrode.
6. The semiconductor device according to claim 4 or 5, wherein the outer edges of the first upper electrode and the second upper electrode are aligned in the stacking direction.
7. The semiconductor device according to claim 4 or 5, wherein the lower electrode is disposed on an insulating film different from the insulating film on which the resistor is located.
8. The semiconductor device according to claim 1 or 4, wherein the resistor contact hole is shallower in depth than the connection wiring contact hole.
9. A substrate (10) having one surface (10a), The wiring layer (20) is arranged on the aforementioned surface and has portions in which a plurality of insulating films (31-34) and a plurality of wiring portions (41-43) are alternately stacked, The wiring layer includes a connection wiring (413) and a resistor (R) comprising a resistance wiring (422b) which is thinner than the connection wiring and arranged on an insulating film different from the insulating film on which the connection wiring is arranged, and a connection wiring contact hole (75) is formed to expose the connection wiring and an electrode (85) connected to the connection wiring is arranged in the connection wiring contact hole, and a resistance contact hole (73, 74) is formed to expose the resistor and which has a different depth from the connection wiring contact hole and an electrode (83, 84) connected to the resistor is arranged in the resistance contact hole. The resistor is made of a conductive material and comprises stopper wiring (422a, 423a, 424a) arranged in the portion where the resistor contact hole is formed, and the resistor wiring arranged on the stopper wiring. A method for manufacturing a semiconductor device, wherein a stopper layer (52) made of a different material from the insulating film is placed on the portion of the resistor in which the contact hole for the resistor is formed, To prepare the substrate having the aforementioned surface, The wiring layer is formed by repeatedly forming the insulating film and forming the wiring portion, and simultaneously forming the resistor contact hole and the connection wiring contact hole, By forming the aforementioned wiring layer, The process involves forming the aforementioned connection wiring, arranging the stopper wiring and the resistance wiring on an insulating film different from the insulating film on which the connection wiring is arranged, and arranging the stopper layer on the resistance wiring. A method for manufacturing a semiconductor device, comprising: performing a first dry etching in which the stopper layer is used as an etching stopper layer to form the resistor contact holes and the connection wiring contact holes to form the resistor contact holes that reach the stopper layer and the connection wiring contact holes that reach the connection wiring; performing a second dry etching in which the resistor contact holes are excavated so that they penetrate the stopper layer and reach the resistor wiring; and performing a reverse sputtering method on the resistor wiring exposed from the resistor contact holes and the connection wiring exposed from the connection wiring contact holes.