Integrated package device, method for manufacturing the same, and memory system
The integrated package device with stacked subpackage modules and redistribution layers addresses inefficiencies in existing semiconductor packaging by enhancing efficiency, density, and heat dissipation, while facilitating high-frequency performance and mass production.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- YANGTZE MEMORY TECH CO LTD
- Filing Date
- 2026-03-12
- Publication Date
- 2026-06-18
AI Technical Summary
Existing packaging techniques for semiconductor chips face challenges such as increased footprint, high cost, and technical difficulty in chip design and packaging, with insufficient assembly efficiency and physical protection in fan-out package structures.
An integrated package device comprising stacked subpackage modules with redistribution layers, through-molding vias, and bonding structures, which include conductive pillars and adhesive layers for efficient heat conduction and magnetic shielding, allowing for vertical stack packaging and increased packaging density.
The solution enhances packaging efficiency, increases packaging density, improves heat dissipation and electromagnetic shielding, reduces wiring pitch, and facilitates high-frequency performance, enabling mass production of flexible capacity packages with reduced fabrication difficulty.
Smart Images

Figure 2026099803000001_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of semiconductor technology, and more particularly, to integrated package devices, methods of fabricating the same, and memory systems.
Background Art
[0002] With the development of chip technology, various packaging techniques have been proposed. Among them, existing packaging techniques using chip stacking include a wiring process and a TSV process. However, the wiring process may expand the footprint of the entire package due to the presence of bonding fingers, and the TSV process requires matching between chip design and chip packaging, which is technically difficult and has a relatively high cost. In recent years, fan-out packages have emerged and are expected to drive the development of chip stack packaging. However, in known fan-out package structures, there are problems of insufficient assembly efficiency and patterns, as well as insufficient physical protection, with respect to the system structure.
[0003] Embodiments of this application provide an integrated package device, a method of fabricating the same, and a memory system that provide efficient heat conduction and magnetic shielding while improving the packaging efficiency and quantity of the fabricated devices.
Summary of the Invention
Means for Solving the Problems
[0004] In one embodiment, the implementation of the present application provides an integrated package device comprising at least one package module. Each package module may include a plurality of first electronic devices and a molding body that encapsulates the plurality of first electronic devices, and each of the first electronic devices may include a first subpackage module having a first pad on its side. Each package module may include a second subpackage module stacked on the side of the first subpackage module, away from the first pad, and comprising a plurality of second electronic devices and a second molding body that encapsulates the plurality of second electronic devices, and each of the second electronic devices may include a second pad on its side. Each package module may include a first redistribution layer positioned on the side of the first subpackage module, away from the second subpackage module, and connected to each of the first pads. Each package module may include a second redistribution layer positioned on the side of the second subpackage module, away from the first subpackage module, and connected to each of the second pads.
[0005] Optionally, the package module may further include through molding vias (TMVs) that extend through a first molding body and a second molding body, connecting a first redistribution layer and a second redistribution layer.
[0006] Optionally, the integrated package device may further include a first bonding structure and a second bonding structure, the first and second bonding structures positioned on and sandwiched between the first and second subpackage modules, respectively, and bonding the first and second bonding structures together.
[0007] Optionally, the integrated package device may further include an external connection structure, which is located on the side of a second redistribution layer, separate from a second subpackage module, and connected to the second redistribution layer.
[0008] Optionally, the external connection structure may include a tin ball array.
[0009] Optionally, the integrated package device may further include a protective layer that covers the side of the first redistribution layer that is separated from the first subpackage module.
[0010] Optionally, the integrated package device may further include an adhesive layer between the first subpackage module and the second subpackage module.
[0011] Optionally, multiple first electronic devices and / or multiple second electronic devices may be stacked in a staircase manner in the direction in which the first subpackage modules and second subpackage modules are stacked, and each first pad of the first electronic device and / or each second pad of the second electronic device may not be covered by any other first electronic device and / or any other second electronic device.
[0012] Optionally, the outer connection surface of the first pad and the outer connection surface of the second pad may face the first redistribution layer and the second redistribution layer, respectively, and the first subpackage module and / or the second subpackage module each further include a first conductive pillar and / or a second conductive pillar, the first conductive pillar and / or the second conductive pillar each electrically connect the first redistribution layer to a portion of the first pad and / or the second redistribution layer to a portion of the second pad.
[0013] Optionally, the outer connection surface of the first pad may face away from the first redistribution layer, or the outer connection surface of the second pad may face away from the second redistribution layer, and the package module further includes gold wires, through which the first pad is connected to the first redistribution layer, or the second pad is connected to the second redistribution layer.
[0014] Optionally, multiple first electronic devices and multiple second electronic devices may be arranged in at least two columns in a transverse direction perpendicular to the direction in which the first and second subpackage modules are stacked; a TMV is located outside one column of electronic devices and away from the other column, and at least one TMV is present.
[0015] Optionally, multiple first electronic devices and multiple second electronic devices may be arranged in at least two columns in a transverse direction perpendicular to the direction in which the first and second subpackage modules are stacked; a TMV is located between the two columns of electronic devices, and at least one TMV is present.
[0016] Optionally, the integrated package device may further include multiple package modules, which are stacked in the direction in which the first and second sub-package modules are stacked. In some implementations, an external connection structure on one of any two adjacent package modules may be connected to the first redistribution layer of the other of the two adjacent package modules. In some implementations, the integrated package device may further include a protective layer that covers the first redistribution layer of the outermost package module in the vertical direction.
[0017] Optionally, the package module may further include an external connection structure, which is located on the side of the second redistribution layer, away from the second electronic device, and connected to the second redistribution layer. In some implementations, the integrated package device may further include multiple package modules stacked in the direction in which the first and second subpackage modules are stacked. In some implementations, an external connection structure on one of any two adjacent package modules may be connected to the first redistribution layer of the other of the two adjacent package modules. In some implementations, the integrated package device may further include a protective layer covering the first redistribution layer of the outermost package module in the vertical direction. In some implementations, the TMVs in the multiple package modules may or may not be aligned in the vertical direction.
[0018] In another embodiment, the implementation of the present application also provides a method for manufacturing an integrated package device. The method may include the step of providing a first subpackage module and a second subpackage module. In some implementations, the first subpackage module may include a plurality of first electronic devices and a first molding body that encapsulates the plurality of first electronic devices. In some implementations, each of the first electronic devices may include a first pad on its side. In some implementations, the second subpackage module may be located on the side of the first subpackage module, away from the first pad. In some implementations, the second subpackage may include a plurality of second electronic devices and a second molding body that encapsulates the plurality of second electronic devices, each of the second electronic devices may include a second pad on its side. The method may include the step of stacking the first subpackage module and the second subpackage module. The method may include the step of forming a first redistribution layer, wherein the first redistribution layer is located on the side of the first subpackage module, away from the second subpackage module, and is connected to a first pad. The method may also include the step of forming a second redistribution layer, wherein the second redistribution layer is located on the side of the second subpackage module, away from the first subpackage module, and is connected to a second pad.
[0019] Optionally, the step of forming a second redistribution layer connected to a second pad may further include the step of forming a through-molding via (TMV), the through-molding via (TMV) extending through the first and second molding bodies and connecting the first and second redistribution layers. In some implementation configurations, the second redistribution layer may be connected to the TMV.
[0020] Optionally, the method may further include the step of forming an external connection structure, which is located on the side of a second redistribution layer, separate from a second subpackage module, and connected to the second redistribution layer.
[0021] Optionally, the step of providing a first subpackage module and a second subpackage module may include arranging a plurality of first electronic devices and a plurality of second electronic devices on a first temporary adhesive layer and a second temporary adhesive layer, such that the outer connection surfaces of the first pads of the first electronic devices each face one same side, and the outer connection surfaces of the second pads of the second electronic devices each face one same side. Optionally, the step of providing a first subpackage module and a second subpackage module may include the step of arranging a first carrier and a second carrier on the sides of a plurality of first electronic devices and a plurality of second electronic devices, respectively, away from a first temporary adhesive layer and a second temporary adhesive layer, wherein the first carrier and the second carrier each have a temporary bonding film facing the plurality of first electronic devices and a plurality of second electronic devices, and the outer connecting surface of the first pad and the outer connecting surface of the second pad each face the first carrier and the second carrier, or face away from the first carrier and the second carrier, respectively. Optionally, the step of providing a first subpackage module and a second subpackage module may include the step of removing the first temporary adhesive layer and the second temporary adhesive layer and forming a first molding body and a second molding body on the first carrier and the second carrier, respectively.
[0022] Optionally, the method may further include the step of positioning the first conductive pillar and the second conductive pillar on a portion of the first pad and a portion of the second pad, respectively, before positioning the first carrier and the second carrier.
[0023] The step of stacking the first subpackage module and the second subpackage module may optionally further include the step of placing an adhesive layer between the first subpackage module and the second subpackage module.
[0024] The step of stacking the first subpackage module and the second subpackage module may optionally further include the step of placing the first bonding structure and the second bonding structure on top of the first subpackage module and the second subpackage module, respectively.
[0025] Optionally, the method may further include the step of forming a protective layer on the side of the first redistribution layer that is separate from the first subpackage module, thereby covering the first redistribution layer.
[0026] Optionally, the method may further include the step of placing the sides of the first subpackage module and the second subpackage module, which are separate from the first carrier and the second carrier respectively, closer together during the step of stacking the first subpackage module and the second subpackage module, such that the first carrier and the second carrier are positioned two outside the combination of the first subpackage module and the second subpackage module. Optionally, the method may further include the step of removing the first carrier and the second carrier before forming the first redistribution layer and the second redistribution layer.
[0027] Optionally, the method may further include providing a plurality of package modules and stacking the plurality of package modules in a direction in which a first sub-package module and a second sub-package module are stacked. Optionally, the method may further include connecting an external connection structure on one of any two adjacent package modules to a first redistribution layer of the other of the two adjacent package modules.
[0028] Optionally, the step of stacking the plurality of package modules in a direction in which a first sub-package module and a second sub-package module are stacked may further include forming a protective layer that covers the first redistribution layer of the outermost package module in the vertical direction.
[0029] In yet another aspect, an implementation form of the present application provides a memory system, and the memory system includes any one of the integrated package devices described above. In some implementation forms, at least one of the first electronic devices and / or at least one of the second electronic devices in the integrated package device includes a memory device, and at least any other one of the first electronic devices and / or at least any other one of the second electronic devices includes a controller used to control the operation of the memory device.
[0030] The integrated package devices, methods for fabricating integrated package devices, and memory systems disclosed in the implementation embodiments of this application can accommodate a large number of semiconductor dies or electronic devices, and by employing a vertical stack packaging scheme, the packaging density can also be increased. On the one hand, the package body can have a system structure with electromagnetic shielding, and the entire package body can have a relatively high proportion of metal. Furthermore, the dies can be arranged continuously, with thermally conductive adhesive films / bonding films between them, so that the entire structure has beneficial heat dissipation. By using redistribution layers (RDLs) instead of conventional gold wiring, the overall wiring pitch can be reduced, the signal transmission speed can be increased, high-frequency performance can be improved, substantially full functionality can be realized, and a system-in-package (SiP) can be realized. Moreover, using the modular packaging solutions disclosed in the implementation embodiments of this application, high-stack structures can be realized, the difficulty of fabricating ultrathin chips for high-capacity high-stack packages can be reduced, mass production can be facilitated, and packages of different capacities can be flexibly fabricated due to the infinite possibilities of stacking. In this way, market demands can be met, and the processing yield of packaging can be beneficially improved.
[0031] To more clearly illustrate the technical solutions in the implementation or in the prior art, the drawings required in the description of the implementation or the prior art are briefly introduced. Clearly, the drawings in the following description represent only a few implementations of this application, and in light of these, the other drawings can be understood by those skilled in the art without any creative work. [Brief explanation of the drawing]
[0032] [Figure 1a] These are cross-sectional structural diagrams of various package modules in an integrated package device provided by the implementation configuration of this application. [Figure 1b] These are cross-sectional structural diagrams of various package modules in an integrated package device provided by the implementation configuration of this application. [Figure 1c] These are cross-sectional structural diagrams of various package modules in an integrated package device provided by the implementation configuration of this application. [Figure 1d] These are cross-sectional structural diagrams of various package modules in an integrated package device provided by the implementation configuration of this application. [Figure 1e] These are cross-sectional structural diagrams of various package modules in an integrated package device provided by the implementation configuration of this application. [Figure 1f] These are cross-sectional structural diagrams of various package modules in an integrated package device provided by the implementation configuration of this application. [Figure 2a] This is a cross-sectional diagram of various combinations of stacked package modules in an integrated package device provided by the implementation of this application. [Figure 2b] This is a cross-sectional diagram of various combinations of stacked package modules in an integrated package device provided by the implementation of this application. [Figure 2c] This is a cross-sectional diagram of various combinations of stacked package modules in an integrated package device provided by the implementation of this application. [Figure 2d] This is a cross-sectional diagram of various combinations of stacked package modules in an integrated package device provided by the implementation of this application, and more specifically, a cross-sectional block diagram of an integrated package device as a memory system. [Figure 3] This is a flowchart of a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4a] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4b] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4c] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4d] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4e] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4f] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4g] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4h] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4i] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 4j] This is a cross-sectional structural diagram corresponding to the main steps for manufacturing a package module in a method for manufacturing an integrated package device provided in the implementation form of this application. [Figure 5] This is a typical cross-sectional diagram of multiple package modules during the stacking step in a method for manufacturing an integrated package device in the implementation form of this application. [Figure 6a] This is a cross-sectional structural diagram illustrating a combination of sub-package modules in a method for manufacturing an integrated package device in the implementation form of this application. [Figure 6b] This is a cross-sectional structural diagram illustrating a combination of sub-package modules in a method for manufacturing an integrated package device in the implementation form of this application. [Modes for carrying out the invention]
[0033] Exemplary implementations of the Disclosure are described in more detail below with reference to the accompanying drawings. While the exemplary implementations of the Disclosure are shown in the drawings, it should be understood that the Disclosure may be implemented in a variety of ways and should not be limited to the specific implementations described herein. Rather, these implementations are provided so that the Disclosure may be more thoroughly understood and the scope of the Disclosure may be fully conveyed to those skilled in the art. Specific details of the structures and functions disclosed herein are merely representative and are used for the purpose of illustrating the exemplary implementations of this application. However, the Application may be implemented in many alternative ways and should not be construed as being limited to the implementations described herein.
[0034] In the description of this application, orientations and positional relationships indicated by terms such as “center,” “lateral,” “upper,” “lower,” “left,” “right,” “vertical,” “horizontal,” “top,” “bottom,” “inside,” and “outside” are based on the drawings and are understood to be solely for illustrative purposes and for the purpose of simplifying the description. There is nothing to indicate or imply that the devices or elements mentioned must have any particular orientation and position, or that they must be constructed or operated in any particular orientation and position. Consequently, they should not be understood as limitations for this application. Furthermore, terms such as “first,” “second,” etc., are used solely for illustrative purposes and should not be understood to indicate or imply relative importance, or to implicitly specify the number of technical features being referenced. Thus, a feature modified by “first” or “second” may explicitly or implicitly include one or more instances of that feature. In the description of this application, “multiple” means two or more unless otherwise specified. Furthermore, the terms "include" and "comprise," and their variations, are intended to cover the meaning of "include or comprise non-exclusively."
[0035] Furthermore, when devices of the same type are modified by the terms "first" and "second," the intention is solely to distinguish between different devices of the same type and to express relative position, rather than any sequence or invariance. In other words, the terms "first" and "second" are interchangeable, and any one of the devices of the same type referred to as "first" may also be referred to as "second."
[0036] It should be noted that in the description of this application, the terms “interconnect” and “connect” should be used broadly. Unless otherwise explicitly specified or limited, they can include, for example, fixed connections, removable connections, or integral connections; mechanical or electrical connections; direct interconnections or interconnections with an intermediate medium; or internal communication between two elements. The specific meaning of the above terms in this application will be understood by those skilled in the art depending on the specific circumstances.
[0037] The terms used herein are for the sole purpose of describing specific implementations and are not intended to limit them. Singular nouns such as "a" and "an" used herein are also intended to include plural nouns unless otherwise explicitly stated in the context. Furthermore, the terms "include" and / or "comprise" used herein are understood to specify the presence of the described features, integers, steps, actions, elements, assemblies, and / or any combination thereof, without excluding the presence or addition of one or more other features, integers, steps, actions, elements, and / or assemblies.
[0038] Fan-out wafer-level packaging (FOWLP) is a novel method for integrating multiple dies obtained from disparate manufacturing processes into a single compact package. Driven by the demand for low-profile and more input / output devices, fan-out wafer-level packaging is gaining increasing attention. With the advancement of FOWLP, single-chip applications are evolving into multi-chip package (MCP) applications and 3D package-on-package (PoP) applications, enabling higher levels of I / O chip integration.
[0039] FOWLP maximizes interconnect density by making full use of RDL for connectivity. Conventional WLP packages are typically fan-in configurations and are used for integrated circuits (ICs) with a small number of pins. As chip area decreases, the number of pins that can be accommodated by the chip also decreases, and as a result, FOWLP packages in a spreading configuration were developed, making full use of RDL for connectivity outside the chip and increasing the number of pins. When each die is embedded in epoxy molding compound (EMC), the gaps between dies each have additional input / output (I / O) connection points, increasing the number of I / Os, improving silicon utilization, maximizing interconnect density, and enabling high-bandwidth data transmission.
[0040] FOWLP (Fan-in Packaging) can reduce package costs and package thickness. In contrast to fan-in packaging techniques, FOWLP offers advantages such as reduced package thickness, increased scalability (increased I / O count), improved electrical and thermal performance, and a baseplate-free process. Fan-out WLP is structurally similar to conventional ball grid array (BGA) packaging but does not require expensive substrate processes.
[0041] Based on the demand for versatile, miniaturized system products, integrated circuit packaging has entered the era of 3D stacking packages. The era of 3D stacking packages is characterized by (1) the evolution from package assemblies to package systems, (2) the development from single-chip applications to multi-chip applications, and (3) the development from in-plane packages (MCMs) to 3D packages. However, effective and efficient package designs that enable the simple operation of 3D packaging and can accommodate various combinations have not yet existed, particularly in the design of memory chips and memory systems. Therefore, this application provides integrated package devices that utilize chip-size package (CSP) and build-up multilayer baseplate techniques, as well as flip connections, via connections, and package-on-package (PoP) techniques, combined with ingenious designs, to provide convenience and accommodate various system packages (especially those including memory). Integrated package devices can integrate chips of various functions (including processors, memory, or any other functional chips) into a single package, realizing substantially complete functionality and forming a system-in-package (SiP).
[0042] In the following sections, the integrated package device, its manufacturing method, and memory system provided by this application are illustrated in several implementation configurations.
[0043] As shown in Figures 1a to 1f, several implementation forms of integrated package devices of this application are illustrated, and in particular, package modules that can facilitate stack packaging and facilitate the formation of integrated package devices are illustrated.
[0044] Firstly, the integrated package devices in some of the implementation configurations of this application can be basic. As shown in Figure 1a, the integrated package device illustrated in the implementation configuration of this application includes at least one package module 100. The package module 100 may mainly include a first subpackage module 110, a second subpackage module 120, a first redistribution layer 130, and a second redistribution layer 140. The first subpackage module 110 may include a plurality of first electronic devices 111 and a first molding body 118 that encapsulates the plurality of first electronic devices. Each of the first electronic devices 111 may include a first pad 112 on its side. The second subpackage module 120 may be stacked on the side of the first subpackage module 110, away from the first pad 112. The second subpackage module 120 may include a plurality of second electronic devices 121 and a second molding body 128 that encapsulates the plurality of second electronic devices. Each of the second electronic devices 121 includes a second pad 122 on its side. The first redistribution layer 130 is located on the side of the first subpackage module 110, away from the second subpackage module 120, and is connected to the first pad 112. The second redistribution layer 140 is located on the side of the second subpackage module 120, away from the first subpackage module 110, and is connected to the second pad 122.
[0045] In some implementations, the first electronic device 111 and the second electronic device 121 may include any active or passive components and may be collectively referred to as the first or second electronic device, respectively. Common passive components are primarily resistors, inductors, and capacitors, characterized by their ability to operate in a circuit without a power supply when a signal is present. Common passive components can be classified into circuit type and connection type according to their function in the circuit. Thus, the first electronic device 111 and / or the second electronic device 121 may include, for example, diodes, resistors, resistor networks, capacitors, inductors, transformers, relays, keys, beeps, speakers, switches, or any other device of the circuit type.
[0046] Active devices are the main devices in electronic circuits and can be classified into various types of discrete devices and integrated circuits according to their physical structure, circuit function, and engineering parameters. Thus, the first electronic device 111 and / or the second electronic device 121 can include, for example, discrete devices such as bipolar transistors (BJTs), field-effect transistors, thyristors, semiconductor resistors, and capacitors (fabricated by an integration process and used in integrated circuits). The first electronic device 111 and / or the second electronic device 121 can also include analog integrated circuit devices such as integrated operational amplifiers, comparators, logarithmic and exponential amplifiers, analog multipliers / dividers, analog switches, phase-locked loops (PLLs), voltage regulators, reference sources, waveform generators, power amplifiers, and power management circuits. The first electronic device 111 and / or the second electronic device 121 may include, for example, digital integrated circuit devices such as basic logic gate circuits, flip-flops, registers, decoders, data comparators, drivers, counters, shaping circuits, PLDs, microprocessors (MPUs), microcontrollers (MCUs), and digital signal processors (DSPs).
[0047] The multiple first electronic devices 111 may be identical to each other or different from each other, and the same can be true for the multiple second electronic devices 121. For example, as shown in the implementation configuration of Figure 1a, the first electronic devices 111 in the first subpackage module 110 may be identical to each other, and the same can be true for the second electronic devices 121 in the second subpackage module 120. They may be semiconductor chips with storage functionality, but are not limited to such chips. Depending on the implementation configuration, any type of chip can be selected for the first electronic devices 111 and the second electronic devices 121.
[0048] As an optional implementation of the combination of the first electronic device 111 and the second electronic device 121, Figure 1b illustrates another exemplary package module 101 of the integrated package device. Package module 101 can differ from package module 100 in terms of the type, number, and / or arrangement of electronic devices. In the implementation shown in Figure 1b, the first subpackage module 110' also includes a plurality of first electronic devices. However, the plurality of first electronic devices can include the first electronic device 111 and a first electronic device 111' that is different from the first electronic device 111. The first electronic device 111 can be, for example, a semiconductor memory chip / die (e.g., DRAM, NAND, NOR, FeRAM, RRAM, or PCRAM). On the other hand, the first electronic device 111' can be, for example, a controller or power management circuit device. The second package module 120' can also include a plurality of second electronic devices. However, the multiple second electronic devices may include a second electronic device 121 and a second electronic device 121' that is different from the second electronic device 121. The second electronic device 121 may be, for example, a semiconductor memory chip / die (e.g., NAND, NOR, FeRAM, RRAM, PCRAM, or DRAM). On the other hand, the second electronic device 121' may be, for example, a passive device (e.g., an inductor or a semiconductor discrete device). Hereafter, the first electronic devices 111 and the second electronic devices 121 may be treated as representative examples to facilitate the explanation, even though the first electronic devices 111 / 111' may be the same as or different from each other, and the second electronic devices 121 / 121' may also be similar as illustrated above.
[0049] In some implementations, both the first electronic device 111 and the second electronic device 121 can be electronic devices. Each electronic device can have a substrate and electronic components on the substrate. The electronic components can include 2D units, 3D memory units, and / or any other suitable components. As used herein, the term “3D memory unit” can refer to a semiconductor device having a memory cell transistor string (also referred to as a “memory string”) extending in a direction perpendicular to the direction of the chip thickness.
[0050] Furthermore, as shown in Figure 1a, each of the first electronic devices 111 has at least one first pad 112 on its side, and / or each of the second electronic devices 121 has at least one second pad 122 on its side. The first pads 112 and the second pads 121 each act as components of a signal transmission path between the corresponding electronic device and an external device (e.g., a signal source or power supply). For ease of illustration, Figure 1a shows that each of the first electronic devices 111 has one first pad 112, and / or each of the second electronic devices 121 has one second pad 122. However, each of the first electronic devices 111 may have multiple first pads 112, and / or each of the second electronic devices 121 may have multiple second pads 122. Each first pad 112 and / or each second pad 122 may include at least one conductive material (for example, but not limited to, a metal and / or a transparent conductive material).
[0051] Still referring to Figure 1a, the first subpackage module 110 and the second subpackage module 120 can each contain two columns of four first electronic devices 111 and two second electronic devices 121 (only two first electronic devices are labeled) stacked sequentially in the longitudinal direction of the figure and in the transverse direction perpendicular to the stacking direction of the two columns on the left and right sides. In other words, multiple first electronic devices 111 and / or multiple second electronic devices 121 are stacked in a staircase configuration in the direction in which the first subpackage module 110 and / or the second subpackage module 120 are stacked. Here, the first pad 112 of each first electronic device 111 and / or the second pad 122 of each second electronic device 121 cannot be covered by any other first electronic device 111 and / or any other second electronic device 121. However, the present application is not limited in this way. For example, when any two first / second electronic devices stacked in sequence are bonded and electrically connected through a bonding structure formed using a bonding adhesive layer, the two electronic devices cannot be stacked in a staircase manner (e.g., in a staircase configuration) such that their first / second pads are not aligned. For example, in the implementation shown in Figure 1b, the first electronic device 111 may be placed in only one layer, and / or the second electronic device 121 may be the same. In this case, it may be unnecessary to consider the stacking configuration and the design of the inter-bonding.
[0052] In the configuration shown in Figure 1a, multiple first electronic devices 111 and / or second electronic devices 121 stacked on top of each other may be bonded to one another through a die attachment film (DAF) or a thermally conductive adhesive film 150. In other words, multiple first electronic devices 111 and / or second electronic devices 121 may be joined through an adhesive layer and bonded electrically through the bonding adhesive layer described above. The application is not limited to such configurations. Instead, in one non-limiting example, the die attachment film / thermally conductive adhesive film 150 may be placed between the opposing stacking surfaces of the first electronic devices 111 and / or second electronic devices 121.
[0053] In some implementations, the first subpackage module 110 and the second subpackage module 120 may be bonded to each other through DAF 150 or any other adhesive film. The first subpackage module 110 and the second subpackage module 120 may be joined through an adhesive layer, and in some non-limiting examples, they may be bonded and electrically connected through the bonding adhesive layer described above. The DAF 150 may be placed on the opposing stacking surfaces of the first subpackage module 110 and the second subpackage module 120, respectively.
[0054] As shown in Figure 1a, the first subpackage module 110 and / or the second subpackage module 120 may also include a vertical first conductive pillar 113 and / or a second conductive pillar 123, respectively. The vertical first conductive pillar 113 and / or the second conductive pillar 123 may each electrically connect the first redistribution layer 130 to a portion of the first pad 112 and / or the second redistribution layer 140 to a portion of the second pad 122. The first conductive pillar 113 and the second conductive pillar 123 may include at least one conductive material (for example, but not limited to, gold, copper, aluminum, silver, and / or any other suitable metal). Due to the use of vertical conductive pillars, the lateral dimensions of the chip package structure 300 may be further reduced.
[0055] In some implementation configurations, as shown in Figure 1b, the conductive layers 132 or 142 in the first redistribution layer 130 or the second redistribution layer 140 may also be electrically connected to the first pad 112 or the second pad 122, respectively, through gold wires 113'.
[0056] That is, the first redistribution layer 130 and the second redistribution layer 140 can be electrically connected to the first pad 112 of the first electronic device 111 and the second pad 122 of the second electronic device 121, respectively, through conductive pillars or gold wires. Also, as shown in Figure 1a, the first subpackage module 110 and / or the second subpackage module 120 can each include a first conductive pillar 113 and / or a second conductive pillar 123, respectively, when the outer connection surfaces of the first pad 112 and the second pad 122 face the first redistribution layer 130 and the second redistribution layer 140, respectively. The first conductive pillar 113 and / or the second conductive pillar 123 can each electrically connect the first redistribution layer 130 to a portion of the first pad 112 and / or the second redistribution layer 140 to a portion of the second pad 122.
[0057] As shown in Figure 1b, the first subpackage module 110 or the second subpackage module 120 in the package module 101 may include gold wire when the outer connection surface of the first pad 112 is positioned away from the first redistribution layer 130, or when the outer connection surface of the second pad 122 is positioned away from the second redistribution layer 140. The gold wire may connect the first pad 112 to the first redistribution layer 130, or the second pad 122 to the second redistribution layer 140.
[0058] As shown in Figures 1a and 1b, the first subpackage modules 110 / 110' and the second subpackage modules 120 / 120' can each include a first molding body 118 and a second molding body 128, respectively. The first molding body 118 and the second molding body 128 can each encapsulate a plurality of first electronic devices 111 and a plurality of second electronic devices 121, forming subpackage modules, respectively, and exposing a first pad 112 and a second pad 122, as well as a first conductive pillar 113 and a second conductive pillar 123 or gold wire 113', respectively. The first molding body 118 and the second molding body 128 can each protect the plurality of first electronic devices 111 and a plurality of second electronic devices 121, respectively, and reduce their physical / chemical damage (e.g., damage from oxidation and moisture). The first molding body portion 118 and the second molding body portion 121 may contain, for example, epoxy resin and / or any other suitable molding compound (including epoxy resin, phenolic resin, catalyst, or silicon dioxide micropowder).
[0059] Still referring to Figures 1a and 1b, the first redistribution layer 130 is located on the side of the first subpackage module 110 / 110' away from the second subpackage module 120 / 120' and may be connected to the first pad 112; the second redistribution layer 140 is located on the side of the second subpackage module 120 / 120' away from the first subpackage module 110 / 110' and may be connected to the second pad 122.
[0060] The first redistribution layer 130 may include at least one conductive layer 132 and at least one insulating layer 131. Each conductive layer 132 may include, for example, a metal, any other suitable conductive material, or any combination thereof. Each insulating layer 131 may include an organic or inorganic material, such as silicon oxide, silicon nitride, silicon oxynitride, any other suitable insulating material, or any combination thereof. Similarly, the second redistribution layer 140 may include at least one conductive layer 142 and at least one insulating layer 141. Each conductive layer 142 may include, for example, a metal, any other suitable conductive material, or any combination thereof. Each insulating layer 141 may include, for example, silicon oxide, silicon nitride, silicon oxynitride, any other suitable insulating material, or any combination thereof. The number of conductive layers 132 / 142 and insulating layers 131 / 141 in the first and second redistribution layers 130 and 140 may be determined according to the practical design. For the sake of illustration, only one conductive layer 132 / 142 is shown as a non-limiting example.
[0061] Still referring to Figure 1a, the insulating layers 131 and 141 of the first and second redistribution layers 130 and 140 each have multiple openings (unlabeled) that expose multiple portions of the corresponding conductive layers 132 and 142 for external connections.
[0062] As a summary of the above description, it can be recognized that the first electronic devices 111 / 111' in the first subpackage module 110 / 110' and the second electronic devices 121 / 121' in the second subpackage module 120 / 120' can contain any type of electronic device and can be arranged and connected side by side or stacked. The connection components between the electronic devices and the first redistribution layer 130 or the second redistribution layer 140 can vary. Therefore, in some further implementation forms described later, the combinations of the first electronic devices 111 / 111' in the first subpackage module 110 / 110' and the second electronic devices 121 / 121' in the subpackage module 120 / 120', as well as the connections between the electronic devices and the first redistribution layer 130 or the second redistribution layer 140, will be described with reference to the combinations in Figure 1a, which are given as non-limiting examples.
[0063] Through the package modules 100 / 101 described above, the main components of a package stack structure are provided as the base for the integrated package device disclosed by the implementation form of this application. That is, the package modules of this disclosure (e.g., integrated package devices) not only house a large number of semiconductor dies or devices as integrated package devices, but also increase the packaging density by employing vertical stack packaging. On the one hand, the package body can have a system structure with electromagnetic shielding, and the entire package body can have a relatively high proportion of metal. The dies can be arranged in a continuous manner, and there can be a thermally conductive film / bonding film between them. As a result, the entire structure has improved heat dissipation. By using RDL instead of conventional gold wiring, the overall wiring pitch can be reduced by more than 40%, the signal transmission speed can be increased, high-frequency performance can be improved, substantially full functionality can be realized, and SiP can be realized. Furthermore, circuit scalability can be enabled by electronic devices using internal or external connection components of the package module. When such package modules are used to complete high-stack structures in the modularized packaging process described below, the difficulty of packaging ultrathin chips for high-capacity high-stack packages is reduced, and mass production can be facilitated. Furthermore, packages of different capacities can be flexibly processed due to the endless possibilities of stacking, meeting market demands and beneficially improving the package processing yield.
[0064] Hereafter, several other implementations are disclosed in accordance with this application, with further reference to Figures 1c and 1d.
[0065] As shown in Figure 1c, package module 102, as an integrated package device according to the implementation configuration of this application, is based on package module 100 as shown in Figure 1a, with the addition of through-molding vias (TMVs) 170. Components in package module 102 that are the same as those in package module 100 will not be repeated here, and only the differences between the two package modules will be described. Still referring to Figure 1c, each through-molding via 170 extends through the first molding body 118 and the second molding body 128, connecting the first redistribution layer 130 and the second redistribution layer 140. Also, as shown in Figure 1c, the plurality of first electronic devices 111 and the plurality of second electronic devices 121 may be arranged in at least two columns, each positioned laterally perpendicular to the direction in which the first subpackage module 110 and the second subpackage module 120 are stacked. Each through-molding via 170 may be positioned outside one column of the electronic device, away from the other column, and at least one through-molding via may be present. However, in some implementation configurations, as shown in Figure 1f, each through-molding via 170 may be positioned between two columns of the electronic device, and at least one through-molding via 170 may be present.
[0066] In several implementation configurations, each through-molding via 170 may include an insulating layer (unlabeled) and a metal layer 170a formed on the inner sidewall of the opening through the first molding body 118. The second molding body 128 and insulator 170b may be filled into the metal layer 170a. The metal layer 170a can connect the conductive layers 132 and 142 in the first redistribution layer 130 and the second redistribution layer 140, and electrically connect the first redistribution layer 130 and the second redistribution layer 140 on the outside of the first subpackage module 110 and the second subpackage module 120, respectively. In this way, circuit connections can be diversified between the electronic devices of the package module 102.
[0067] In contrast to wire bonding, 3D interconnect techniques such as through-molding vias (TMV) 170 can be used to achieve shorter interconnect paths, lower resistance and inductance, and more efficient signal and power transmission, resulting in improved or faster signal transmission throughout the package module, improved high-frequency performance of the product, no limitations on the number of stacked dies, less operation-intensive manufacturing and design processes, and potentially reduced manufacturing costs.
[0068] Furthermore, according to some implementations of this application, as shown in Figure 1d, the package module 103 is depicted as an integrated package device, similar to the package module 100 shown in Figure 1a. However, it differs in that, instead of using the DAF 150, the first bonding structure 114 and the second bonding structure 124 are included on the bonding surfaces of the electronic devices on the bonding sides of the first subpackage module 110'' and the second subpackage module 120'', respectively, bonding the first subpackage module 110'' and the second subpackage module 120'' together to achieve circuit connectivity.
[0069] In several implementation configurations, the first bonding structure 114 and the second bonding structure 124 may have the same structure, each having at least one bonding insulating layer 1141 / 1241 and at least one bonding contact 1142 / 1242 extending longitudinally through the bonding insulating layer 1141 / 1241. The bonding contacts 1142 and 1242 connect the circuit interconnection layers (not shown) in the first electronic device 111 and the second electronic device 121, and through the first bonding structure 114 and the second bonding structure 124, directly realize mechanical and electrical connections between the first subpackage module 110'' and the second subpackage module 120'' in the package module 103. The material of each bonding insulating layer 1141 / 1241 may include, for example, silicon oxide, silicon nitride, silicon oxynitride, any other suitable insulating material, or any combination thereof. The material of each bonding contact 1142 / 1242 may, without limitation, include at least one conductive material (e.g., gold, copper, aluminum, silver, and / or any other suitable metal). Various bonding techniques may be used to facilitate the structures described above.
[0070] The fabrication process for the TMV can be omitted by providing the first bonding structure 114 and the second bonding structure 124 to replace the TMV described above. However, the bonding structure can be provided in addition to the TMV to achieve a function equivalent to that obtained by the TMV 170 described above. As previously stated, multiple first electronic devices 111 in the first subpackage module 110 / 110" or multiple second electronic devices 121 in the second subpackage module 120 / 120" can be mechanically and / or electrically connected through the bonding structure described above to achieve a conductive connection.
[0071] As another summary of the above description, in contrast to package modules 100 / 101, package modules 102 / 103 described above have an additional TMV or bonding structure, and therefore not only constitute a major component of the package stack structure as the base of the integrated package device, but also provide more possibilities for circuit connections for flexibility of application. In this way, the combination of package modules can be used more flexibly in any subsequent package stack structure.
[0072] Referring further to Figures 1e and 1f, basic package modules of integrated package devices in several implementation configurations of this application are disclosed.
[0073] As shown in Figure 1e, package module 104 is shown as an integrated package device. Based on package module 102 illustrated in Figure 1c, package module 104 has an additional external connection structure 190, which is located on the side of the second redistribution layer 140, away from the second subpackage module 120, and is connected to the second redistribution layer 140.
[0074] As shown in Figure 1f, package module 105 is also illustrated as an integrated package device. Similar to package module 104 described above, package module 105 also has an additional external connection structure 190, which is located on the side of the second redistribution layer 140, away from the second subpackage module 120, and connected to the second redistribution layer 140. However, package module 105 differs from package module 104 in terms of the location of each TMV 170. That is, in package module 105, the multiple first electronic devices 111 and the multiple second electronic devices 121 are each arranged in at least two columns that are arranged laterally perpendicular to the direction in which the first subpackage module 110 and the second subpackage module 120 are stacked. Here, the TMV 170 is not located outside one column of electronic devices and away from the other column, but rather is located between the two columns of electronic devices, and it is possible for at least one TMV 170 to be present.
[0075] In some implementations, the external connection structure 190 may include, but is not limited to, an array of tin balls, and may also include, for example, tin paste, conductive glue, or bonding contacts. The tin balls are arranged in a number of outward-facing openings (unlabeled) within the insulating layer 141 described above and are electrically connected to the exposed portions of the conductive layer 142. Using the tin balls of the external connection structure 190 as signal input / output terminals, signals from an external device may be input into the package module 104 / 105, and signals from the package module 104 / 105 may be output to the external device.
[0076] Furthermore, while still referring to Figures 1e and 1f, the external connection structure 190 is depicted as being located on the side of the second redistribution layer 140, away from the second subpackage module 120, and connected to the second redistribution layer 140; however, it should be understood that this depiction is merely for illustrative purposes. Nevertheless, it should be understood that the external connection structure 190 can be located on the side of the first redistribution layer 130, away from the first subpackage module 110, and connected to the first redistribution layer 130, without departing from the scope of this disclosure. Therefore, it should be recognized that the terms “first” or “second” in this specification do not imply “upper” or “lower,” and may be interchangeable without departing from the scope of this application, provided that the relative relationship is satisfied.
[0077] In the integrated package device disclosed in the implementation form of this application, multiple package modules may be stacked using package modules 104 / 105 with an additional external connection structure 190, and their external connection may be achieved by directly using package modules 104 / 105 as units. However, it should be understood that even if only the structures of the package modules 102 / 103 described above exist, multiple package modules may be stacked and connected externally. This is because, at the very least, the external connection structure 190 is a component that may be added when device mounting is performed, or multiple package modules may be stacked by a downstream manufacturer. Therefore, the integrated package device disclosed herein may be, or may include, any one of the package modules 100, 101, 102, 103, 104, and 105 described above.
[0078] According to the implementation of this application, there are various integrated package devices that can be obtained using various stacking combinations utilizing any of the various package modules 100, 101, 102, 103, 104, and 105 described above. In other words, based on package modules 100, 101, 102, 103, 104, and 105, the integrated package devices disclosed by the implementation of this application may include one or more package modules.
[0079] For example, referring to Figure 2a, an implementation configuration is illustrated in which the integrated package device disclosed in this application is fabricated from a single package module. As shown in Figure 2a, the integrated package device 201 includes a package module 105 (for example, depicted in Figure 1e) and a protective layer 160 covering a first redistribution layer 130 on the side away from the first subpackage module 110.
[0080] In some implementation configurations, the material of the protective layer 160 can be the same as that of the first / second molding body 118 / 128 described above, and can include epoxy resin and / or any other suitable molding compound (e.g., epoxy resin, phenolic resin, catalyst, and silicon dioxide micropowder). The protective layer 160 can protect the first redistribution layer 130 from physical and / or chemical damage by oxidation and moisture, for example.
[0081] In the integrated package device 201 shown in Figure 2a, a vertical stack packaging scheme is used, which enables the following effects: accommodating a large number of semiconductor dies or devices, increasing packaging density, and having electromagnetic shielding in the package body. The entire package body has a high proportion of metal, the dies are arranged in a continuous manner, and there is a thermally conductive adhesive / bonding film between them, allowing for better heat dissipation for the entire structure.
[0082] As shown in Figure 2b, the integrated package device disclosed by the present application is illustrated in an implementation configuration in which it is made from two package modules.
[0083] Referring to Figure 2b, the integrated package device may include multiple instances of package modules. These package modules may be stacked in a direction in which a first sub-package module and a second sub-package module are stacked. An external connection structure on one of any two adjacent package modules may be connected to the first redistribution layer of the other of the two adjacent package modules. The integrated package device may further include a protective layer covering the first redistribution layer of the outermost package module in the vertical direction.
[0084] Still referring to Figure 2b, the integrated package device 202 can include two package modules 104 (each as shown in Figure 1e) stacked sequentially in the direction in which the first subpackage module 110 and the second subpackage module 120 are stacked. The tin ball 190 (external connection structure) of the lower package module 104 acts as a member connected to the first redistribution layer 130 in the upper package module 104. The integrated package device 202 further includes a protective layer 160 that covers the first redistribution layer 130 of the outermost package module 104 in the vertical direction (for example, located on the bottom surface of the lower package module 104). The tin ball 190 (external connection structure) of the lower package module 104 acts as a member connected to the first redistribution layer 130 in the upper package module 104. The integrated package device 202 further includes a protective layer 160, which covers the first redistribution layer 130 of the outermost package module 104 in the vertical direction (for example, located on the bottom surface of the lower package module 104).
[0085] Using an integrated packaging device 202 as shown in Figure 2b, the difficulty of processing ultrathin chips / dies for high-capacity, high-stack packages is reduced, facilitating mass production. Packages of different capacities can be flexibly processed due to the endless possibilities of stacking, meeting market demands and beneficially improving package processing yield.
[0086] Referring to Figure 2c, an integrated package device is shown containing multiple package modules (for example, three package modules). The multiple package modules may be stacked in the direction in which the first sub-package module and the second sub-package module are stacked. An external connection structure on one of any two adjacent package modules may be connected to the first redistribution layer of the other of the two adjacent package modules. The integrated package device may further include a protective layer that covers the first redistribution layer of the outermost package module in the vertical direction. The TMVs of the multiple package modules may or may not be vertically aligned.
[0087] The integrated package device 203 depicted in Figure 2c may include two package modules 104 (each as shown in Figure 1e) stacked vertically, one on top of the other, and one package module 105 sandwiched between them. In other words, the three package modules may be stacked on top of each other in the direction in which the first sub-package module 110 and the second sub-package module 120 within any of the package modules are stacked. The tin ball 190 (external connection structure) on the lower package module 104 acts as a member connected to the first redistribution layer 130 in the package module 105. The tin ball 190 on the package module 105 may act as a member connected to the first redistribution layer 130 in the package module 104. The integrated package device 203 further includes a protective layer 160 covering the first redistribution layer 130 of the outermost package module 104 vertically (for example, located on the bottom surface of the bottom package module 104). Furthermore, the TMV170 in each package module is either aligned or not aligned vertically. That is, the TMV170 in each package module 104 and the TMV170 in package module 105 are not aligned, while the TMV170 in the top package module 104 and the TMV170 in the bottom package module 104 are aligned.
[0088] An integrated package device 203, as shown in Figure 2c, can achieve the same effect as an integrated package device 202, as shown in Figure 2b. Furthermore, although not shown in the figures, the illustrations of integrated package devices 202 and 203 can be seen to indicate that any number of package modules 100, 101, 102, 103, and 104 can be used in any combination and arrangement. For example, four or even five package modules can be stacked on top of each other. Electronic devices can also be used in any combination, as previously described; for example, each vertical column can contain one, two, three, or four electronic devices, and this is not an limitation.
[0089] Some implementations of this application further provide a memory system comprising an integrated package device using any of the previously described combinations. In the memory system, at least one of the first electronic devices and / or at least one of the second electronic devices of the integrated package device comprises a memory device, and at least any other one of the first electronic devices and / or at least any other one of the second electronic devices comprises a controller used to control the operation of the memory device.
[0090] As shown in Figure 2d, an integrated package device 204 as a memory system is illustrated. In Figure 2d, each electronic device is represented by a box containing the name of the corresponding device, with the corresponding reference number omitted. For example, the electronic devices represented by boxes include DRAM, controller 1, NAND 1-8, dies 1-4, controller 2, and power management die. Referring to the positions corresponding to the first electronic device in the first sub-package module below each package module and the second electronic device in the second sub-package module above each package module, the first electronic device 111 in the integrated package device 204 may include NAND 1-4, dies 1-2, controller 2, and power management die. On the other hand, the second electronic device 121 may include DRAM, controller 1, NAND 5-8, and dies 3-4. The memory system may include electrically connected memory and controllers. The controllers may be used to control the data storage of the memory. The memory and controllers may be well known to those skilled in the art and are not described in detail here. Memory systems can be applied to computers, televisions, set-top boxes, or in-vehicle terminal products, among others.
[0091] Still referring to Figure 2d, the integrated package device 204 is capable of functioning as a memory system; at least one of the first electronic devices and / or at least one of the second electronic devices in the integrated package device includes a memory device, and at least any other one of the first electronic devices and / or at least any other one of the second electronic devices includes a controller used to control the operation of the memory device.
[0092] Several implementations of integrated package devices according to this application have been described above, and methods for manufacturing such integrated package devices according to several other implementations of this application are further provided. As shown in Figure 3, methods for manufacturing integrated package devices according to several implementations of this application may include the following operations.
[0093] Referring to Figure 3, in operation S100, a first subpackage module and a second subpackage module are provided. The first subpackage module includes a plurality of first electronic devices, and the first molding body can encapsulate the plurality of first electronic devices. Each of the first electronic devices can include a first pad on its side. The second subpackage module can be located on the side of the first subpackage module, away from the first pad. The second subpackage module can include a plurality of second electronic devices and a second molding body that encapsulates the plurality of second electronic devices. Each of the second electronic devices can include a second pad on its side.
[0094] In operation S300, the first subpackage module and the second subpackage module are stacked.
[0095] In operation S500, a first redistribution layer is formed on the side of the first subpackage module, away from the second subpackage module, and is connected to the first pad.
[0096] In operation S700, a second redistribution layer is formed on the side of the second subpackage module, away from the first subpackage module, and is connected to the second pad.
[0097] Referring again to operation S100, the first subpackage module and the second subpackage module can be provided in many ways, one of which is taken as a representative example and may further include the following substeps.
[0098] For example, in operation S110, a plurality of first electronic devices and a plurality of second electronic devices are placed on a first temporary adhesive layer and a second adhesive layer, respectively, with the first pad of the first electronic device and the second pad of the second electronic device facing the same side.
[0099] In operation S120, the first conductive pillar and the second conductive pillar are positioned on a portion of the first pad and a portion of the second pad, respectively.
[0100] In operation S130, the first carrier and the second carrier are arranged on the sides of a plurality of first electronic devices and a plurality of second electronic devices, respectively, away from the first temporary adhesive layer and the second temporary adhesive layer, and the temporary bonding film is made to face the plurality of first electronic devices and a plurality of second electronic devices, respectively, with the first pad and the second pad facing the first carrier and the second carrier, respectively, or facing away from the first carrier and the second carrier.
[0101] In operation S140, the first temporary adhesive layer and the second temporary adhesive layer are removed, and the first molding body and the second molding body are formed on the first carrier and the second carrier, respectively.
[0102] Referring again to operation S300, the first subpackage module and the second subpackage module can be stacked in many ways, one of which is taken as representative. That is, operation S300 may further include the steps of: positioning the first carrier and the second carrier on two sides of the combination of the first molding body and the second molding body; and removing the first carrier and the second carrier before forming the first redistribution layer and the second redistribution layer.
[0103] Similarly, various operations may be added between operations S100 and S300, depending on the selected structure of the integrated package device, and two of these operations are given as representative examples.
[0104] For example, in operation S200, an adhesive layer may be placed between the first subpackage module and the second subpackage module. In operation S210, the first bonding structure and the second bonding structure may be placed on the first subpackage module and the second subpackage module, respectively.
[0105] Furthermore, after forming the first redistribution layer in operation S500 and before performing operation S700, many operations can be added depending on the selected structure of the integrated package device. For example, operation S550 may be optionally added, which includes forming a protective layer on the side of the first redistribution layer that is separate from the first subpackage module in order to cover the first redistribution layer.
[0106] Furthermore, referring to the integrated package device having TMV depicted in Figure 1c, the method for fabricating the integrated package device may further include the following optional steps in operation S700 when the second redistribution layer is formed.
[0107] For example, in operation S600, the TMV is formed so as to extend through the first molding body and the second molding body, and so as to be connected to the first redistribution layer and the second redistribution layer; the second redistribution layer is connected to the TMV.
[0108] Furthermore, the method for manufacturing integrated package devices can include applying a completed basic package module.
[0109] For example, in operation S800, an external connection structure is formed on the side of the second redistribution layer, which is separated from the second subpackage module, and is connected to the second redistribution layer.
[0110] In operation S900, multiple package modules are provided, stacked in a direction in which a first subpackage module and a second subpackage module are stacked. An external connection structure on one of any two adjacent package modules may be connected to the first redistribution layer of the other of the two adjacent package modules.
[0111] The various possible operations in the method of fabricating integrated package devices are described in detail with reference to the cross-sectional structural diagrams in Figures 4a to 4j.
[0112] For example, referring to Figures 4a to 4c, the operation S100 of Figure 3 is performed, providing, for example, a first subpackage module and a second subpackage module. The first subpackage module includes a plurality of first electronic devices and a first molding body that encapsulates the plurality of first electronic devices, each of which may include a first pad on its side. The second subpackage module is located on the side of the first subpackage module, away from the first pad, and includes a plurality of second electronic devices and a second molding body that encapsulates the plurality of second electronic devices, each of which includes a second pad on its side.
[0113] In some implementations, the first and second subpackage modules may have the same or different combinations of electronic devices, as shown in Figures 1a and 1b, but can be manufactured using essentially the same methods. Therefore, in the following description, combinations such as those shown in Figure 1a may be taken as representative for illustrative purposes, and if it is not necessary to describe the second subpackage module 120 at the same time, only the first subpackage module 110 will be described as representative, with the device description of the second subpackage module enclosed in parentheses.
[0114] For example, operation S100 may include sub-operations S110 to S140. As shown in Figure 4a, operation S110 of Figure 3 is performed, for example, with a plurality of first electronic devices 111 (and a plurality of second electronic devices) each placed on a first temporary adhesive layer 115 (and a second temporary adhesive layer) with the first pads 112 on the first electronic devices 111 (and the second pads on the second electronic devices) each facing the same side. The plurality of first electronic devices 111 stacked vertically may be fixed together with DAF 150 or any suitable adhesive material between them, but this is not limited to.
[0115] As also shown in Figure 4a, operation S120 is performed so that, for example, a first conductive pillar 113 (and a second conductive pillar) protruding in the direction in which the first electronic device 111 is stacked is positioned on a portion of the first pad 112 (and a portion of the second pad), respectively.
[0116] In this specification, according to integrated package devices in some implementation forms of this application, such as those shown in Figures 1a and 1b, this operation is not limited to arranging conductive pillars, and gold wires may be arranged as per the design. Therefore, any device for guiding from the pads may be used. However, it can be recognized that conductive pillars have the advantage of saving lateral space.
[0117] Next, as shown in Figure 4b, the operation S130 of Figure 3 is performed, for example, the first carrier 116 (and the second carrier) is positioned on the sides of the multiple first electronic devices 111 (and the multiple second electronic devices) that are away from the first temporary adhesive layer 115 (and the second temporary adhesive layer), and the temporary bonding film 116a is positioned to face the multiple first electronic devices (and the multiple second electronic devices) with the first pad 112 (and the second pad, respectively) facing the first carrier 116 (and the second carrier).
[0118] For example, as shown in Figure 4b, before the first electronic device 111 is placed on the first carrier 116, the stacked first electronic devices 111 may be inverted so that the first electronic devices 111 not bonded to the first temporary adhesive layer 115 can be bonded to the temporary bonding film 116a of the first carrier 116. It can be recognized that whether or not to invert the first electronic devices 111 may be determined depending on the manner in which the first pad 112 is connected to the temporary film 116a. For example, when the connection is realized through a gold wire 113', as shown in Figure 1b, it may not be necessary to invert the multiple first electronic devices 111. Additionally and / or alternatively, the first carrier 116 may be attached directly to the sides of the first electronic devices away from the first temporary adhesive layer 115 without inversion, then inversion is performed and the next operation is carried out.
[0119] Next, as shown in Figures 4b and 4c, operation S140 of Figure 3 is performed. For example, the first temporary adhesive layer 115 (and the second temporary adhesive layer) are removed, and the first molding body 118 (and the second molding body) are formed on the first carrier 116 (and the second carrier), completing the first subpackage module 110 (and the second subpackage module). The material of the molding body has been described above and will not be repeated here.
[0120] After the first subpackage module and the second subpackage module are completed using the suboperations described above, the above operation S100 that provides the first subpackage module and the second subpackage module may be completed.
[0121] Next, the main operation S300 described above may be performed, which involves stacking the first subpackage module and the second subpackage module.
[0122] For example, referring to Figure 4d, in order to stack the first subpackage module and the second subpackage module, the sides of the first subpackage module 110 and the sides of the second subpackage module 120 are set close together, with the first carrier 116 and the second carrier 126 positioned two sides outside the combination of the first subpackage module 110 and the second subpackage module 120, respectively.
[0123] According to several implementations of this application, different alternative operations may be used to stack the first subpackage module and the second subpackage module, depending on the different structure of the integrated package device.
[0124] With respect to the first type of step, as shown in Figure 4d, operation S200 of Figure 3 is performed, for example, by positioning the DAF150 between the first subpackage module 110 and the second subpackage module 120, and firmly joining them together from the top and bottom sides, respectively.
[0125] With respect to the second type of step, as shown in Figures 6a and 6b, operation S210 of Figure 3 is performed, for example, by placing the first bonding structure 114 and the second bonding structure 124 on the bonding surface of the electronic device at the bonding side of the first subpackage module 110'' and the bonding side of the second subpackage module 120'', respectively, and bonding the first subpackage module 110'' and the second subpackage module 120'' together, thereby achieving a conductive connection by joining the first bonding structure 114 and the second bonding structure 124 under heat or pressure. Various bonding techniques may be used for bonding as described herein, without limitation.
[0126] After the first subpackage module and the second subpackage module are bonded together to form a combination, the main operation S500 is performed. In operation S500, the first redistribution layer 130 is formed on the side of the first subpackage module 110 that is separated from the second subpackage module 120 and connected to the first pad 112. However, the first carrier 116 is removed before the formation of the first redistribution layer 130. Furthermore, the second carrier 126 is also removed before the subsequent formation of the second redistribution layer 140.
[0127] For example, the operation S500 of Figure 3 is carried out as shown in Figures 4e and 4f. As an example, the first carrier 116 is removed before the formation of the first redistribution layer 130, and then the first redistribution layer 130 is formed in the place where the first carrier was before removal. During the formation of the first redistribution layer 130, referring to the above description, an insulating layer 131 is formed, then a conductive layer 132 is formed, and then another insulating layer 131 is formed covering the conductive layer 132. Openings (unlabeled) are formed in appropriate locations for external connections. The conductive layer 132 may include a metal, any other suitable conductive material, or any combination thereof, and the insulating layer 131 may include an organic or inorganic material, such as silicon oxide, silicon nitride, silicon oxynitride, any other suitable insulating material, or any combination thereof. The number of conductive layers 132 and insulating layers 131 in the first redistribution layer 130 may be determined. For practical design purposes and for convenience, only one conductive layer 132 is shown as a non-limiting example.
[0128] Still referring to Figures 4e and 4f, operation S550 of Figure 3 is carried out, for example, by forming protective layers 160 / 160a on the side of the first redistribution layer 130 away from the first subpackage module 110 and covering the first redistribution layer 130.
[0129] Figures 4e and 4f differ in that Figure 4e shows the protective layer 160, while Figure 4f shows the temporary protective layer 160a. The protective layer 160 and the temporary protective layer 160a are collectively referred to as the “protective layer” and may be selected for use depending on the subsequent application of the package module. In other words, if the first redistribution layer 130 is on the outermost side in the stack of the package module that will be formed later, as shown in Figure 4e, the same material as the first molding body 118 may be used for the protective layer. If the first redistribution layer 130 is in the middle of the stack of the package module, as shown in Figure 4f, the temporary protective layer 160a may be selected to be easily removable and has materials common in the art. By example and without limitation, polyimide, polybenzoxazole, phenol, and / or any combination of other resins / materials may be used as the temporary protective layer 160a. When a package module is to be stacked with other package modules, the temporary protective layer 160a may be removed to facilitate electrical connection between the first redistribution layer 130 and other devices. It should be recognized that the formation of the temporary protective layer 160a may be an optional operation.
[0130] Next, operation S700 may be performed, in which a second redistribution layer is formed on the side of the second subpackage module, away from the first subpackage module, and connected to the second pad.
[0131] Referring to Figures 4g and 4h, after the formation of the first redistribution layer 130, the combination of the first subpackage module 110 and the second subpackage module 120 is inverted upside down, and the second redistribution layer 140 is formed on the side of the second subpackage module 120 away from the first subpackage module 110 and connected to the second pad 122. To reduce the number of figures, an optional TMV 170 relating to operation S600 is also shown in Figures 4g and 4h. The difference between Figure 4g and Figure 4h is the same as the difference between Figure 4e and Figure 4f. In other words, it is the formation of protective layers 160 and 160a. Similarly, before the formation of the second redistribution layer 140, the corresponding second carrier 126 is removed, and the second redistribution layer 140 is formed in the same location as the second carrier 126 before its removal. The style and material for forming the second redistribution layer 140 can be the same as those for forming the first redistribution layer 130, and are not repeated here. At this point, a basic unit of the integrated package device (e.g., one package module 106 / 106') is complete.
[0132] Regarding different designs, it should be noted that, as an optional choice, the TMV170 corresponding to operation S600 may be selectively formed simultaneously with the second redistribution layer 140. In other words, when bonding structures 114 / 124 as shown in Figures 6a and 6b are formed, the TMV170 may or may not be implemented, and even if a bonding structure is not formed, the TMV170 may not necessarily be provided.
[0133] As shown in Figures 4g and 4h, before the formation of the two insulating layers 141, through molding openings (unlabeled) are formed in the first subpackage module 110 and the second subpackage module 120, and during the formation of one insulating layer 141, the insulating layer 141 material is also filled into the through molding openings. Then, during the formation of the conductive layer 142 in the second redistribution layer 140 and the subsequent formation of the insulating layer 141 on top of it, the conductive layer 142 and insulating layer 141 material is also filled into the TMV so that the TMV 170 is formed in coordination with the second redistribution layer 140. Similar to the insulating layer 131, the insulating layer 141 may be used to cover the conductive layer 142 and has openings (unlabeled) which are positioned appropriately and used to accommodate tin balls 190 for external connections.
[0134] As shown in Figures 4i and 4j, operation S800 is optionally performed after the formation of the first redistribution layer 130 and the second redistribution layer 140. For example, an external connection structure is formed on the side of the second redistribution layer 140, away from the second subpackage module, and connected to the second redistribution layer.
[0135] As shown in Figures 4i and 4j, the external connection structure 190 (e.g., tin ball 190) is filled into the opening (unlabeled) in the insulating layer 141 of the second redistribution layer 140. This operation is optional, because the package module 106 / 106' completed in step S700 can function as an integrated package device on its own. Furthermore, the tin ball can be added by the user when using an integrated package device (e.g., a single package module).
[0136] Hereafter, a method for fabricating an integrated package device including a plurality of package modules disclosed in the implementation embodiment of this application will be described. That is, operation S900 will be performed. Here, a plurality of package modules will be provided and stacked in a manner in which a first subpackage module and a second subpackage module are stacked; and an external connection structure on one of any two adjacent package modules will be connected to the first redistribution layer of the other of the two adjacent package modules.
[0137] As shown in Figure 5, operation S900 of Figure 3 is performed. For example, package modules (such as those represented by any of the package modules 104, 105, and 107 as shown in Figures 1e, 1f, and 4i, respectively) are stacked on top of each other, the tin balls 190 are heated and melted, and then planarized. In this way, an integrated package device 203 as shown in Figure 2c can be obtained after reflow and curing.
[0138] In several implementation forms of this application, the method for fabricating integrated package devices described above is used to provide integrated package devices that offer convenience and are adaptable to various system packages (particularly those including memory). Integrated package devices integrate chips of various functions (including processors, memory, or any other functional chips) into a single package, realizing substantially complete functionality and forming a SiP. Furthermore, the difficulty of fabricating ultrathin chips for high-capacity, high-stack packages is reduced, enabling mass production, and packages of different capacities can be flexibly fabricated due to the infinite possibilities of stacking, meeting market demands and beneficially improving package fabrication yield.
[0139] In summary, integrated package devices, methods for manufacturing integrated package devices, and memory systems in several implementation forms of this application have been described above. However, this application is not defined by those implementation forms. Alternative and modified examples can be made for the above implementation forms by those skilled in the art to obtain other implementation forms without departing from the scope and spirit of this application. All technical solutions formed by identical or equivalent substitutions fall within the scope of this application. Thus, the scope of this application is defined by the claims. [Explanation of symbols]
[0140] 100 package modules 101 Package Modules 102 Package Modules 103 Package Modules 104 Package Modules 105 Package Modules 106 Package Modules 106' Package Module 107 Package Modules 110 First subpackage module 110' First subpackage module 110'' First subpackage module 111 First Electronic Device 111' First Electronic Device 112 First pad 113 First conductive pillar 113' Gold wire 114 First Bonding Structure 1141 Bonding insulating layer 1142 Bonding Contacts 115 First temporary adhesive layer 116 First Career 116a Temporary bonding film 118 First molding body 120 Second subpackage module 120' Second package module 120'' Second subpackage module 121 Second Electronic Device 121' Second Electronic Device 122 Second pad 123 Second conductive pillar 124 Second Bonding Structure 1241 Bonding Insulation Layer 1242 Bonding Contacts 126 Second Career 128 Second molding body 130 First redistribution layer 131 Insulating layer 132 Conductive layer 140 Second redistribution layer 141 Insulating layer 142 Conductive layer 150 Die Attachment Film (DAF), Thermally Conductive Adhesive Film 160 protective layer 160a Temporary protective layer 170 Through-Molding Vias (TMV) 170a metal layer 170b Insulator 190 External connection structure 201 Integrated Package Devices 202 Integrated Package Devices 203 Integrated Package Devices 204 Integrated Package Devices
Claims
1. An integrated package device comprising at least one package module, wherein each package module is A first subpackage module comprising a plurality of first electronic devices and a first molding body portion encapsulating the plurality of first electronic devices, each of the first electronic devices having a first pad on its side; A second subpackage module is stacked on the side of the first subpackage module, away from the first pad, and includes a plurality of second electronic devices and a second molding body that encapsulates the plurality of second electronic devices, each of which includes a second pad on its side; A first redistribution layer is located on the side of the first subpackage module, away from the second subpackage module, and connected to each of the first pads; A second redistribution layer is located on the side of the second subpackage module, away from the first subpackage module, and is connected to each of the second pads. An integrated package device, including an integrated package device.
2. Each package module is, Through-molding vias (TMVs) extend through the first molding body and the second molding body and connect the first redistribution layer and the second redistribution layer. The integrated package device according to claim 1, further comprising:
3. The integrated package device according to claim 1, further comprising a first bonding structure and a second bonding structure, the first bonding structure and the second bonding structure being positioned between the first subpackage module and the second subpackage module, and respectively positioned on the first subpackage module and the second subpackage module, and the first bonding structure and the second bonding structure bonding the first subpackage module and the second subpackage module together.
4. The integrated package device according to any one of claims 1 to 3, further comprising an external connection structure, the external connection structure being located on the side of the second redistribution layer, away from the second subpackage module, and connected to the second redistribution layer.
5. The integrated package device according to claim 4, wherein the external connection structure includes an array of tin balls.
6. The integrated package device according to any one of claims 1 to 3, further comprising a protective layer covering the side of the first redistribution layer that is separated from the first subpackage module.
7. The integrated package device according to claim 2, further comprising an adhesive layer positioned between the first subpackage module and the second subpackage module.
8. The integrated package device according to claim 1, wherein the plurality of first electronic devices and / or the plurality of second electronic devices are stacked in a staircase manner in the direction in which the first subpackage module and the second subpackage module are stacked, and the first pad of each of the first electronic devices and / or the second pad of each of the second electronic devices are not covered by any other part of the first electronic device and / or any other part of the second electronic device.
9. The integrated package device according to claim 1 or 8, wherein the outer connection surface of the first pad and the outer connection surface of the second pad face the first redistribution layer and the second redistribution layer, respectively, and the first subpackage module and / or the second subpackage module each further include a first conductive pillar and / or a second conductive pillar, the first conductive pillar and / or the second conductive pillar each connect the first redistribution layer to a portion of the first pad and / or the second redistribution layer to a portion of the second pad.
10. The integrated package device according to claim 1, wherein the outer connection surface of the first pad faces away from the first redistribution layer, or the outer connection surface of the second pad faces away from the second redistribution layer, and the package module further includes a gold wire, through which the first pad is connected to the first redistribution layer, or the second pad is connected to the second redistribution layer.
11. The aggregated package device according to claim 2, wherein the plurality of first electronic devices and the plurality of second electronic devices are arranged in at least two columns of the electronic device in a transverse direction perpendicular to the direction in which the first subpackage modules and the second subpackage modules are stacked; and the TMV is positioned outside one column of the electronic device and away from the other column, and at least one TMV is present.
12. The integrated package device according to claim 2, wherein the plurality of first electronic devices and the plurality of second electronic devices are arranged in at least two columns of the electronic devices in a transverse direction perpendicular to the direction in which the first subpackage modules and the second subpackage modules are stacked; and the TMV is located between the two columns of the electronic devices and at least one TMV is present.
13. The integrated package device according to claim 4, comprising a plurality of the package modules, the plurality of package modules stacked in a direction in which the first subpackage module and the second subpackage module are stacked, the external connection structure on one of any two adjacent package modules is connected to the first redistribution layer of the other of the two adjacent package modules; the integrated package device further comprises a protective layer covering the first redistribution layer of the outermost package module in the vertical direction.
14. The package module further includes an external connection structure, the external connection structure being located on the side of the second redistribution layer, away from the second electronic device, and connected to the second redistribution layer; The integrated package device further includes a plurality of the package modules stacked in the direction in which the first subpackage module and the second subpackage module are stacked, The external connection structure on one of any two adjacent package modules is connected to the first redistribution layer of the other of the two adjacent package modules; The integrated package device further includes a protective layer that covers the first redistribution layer of the outermost package module in the vertical direction; The integrated package device according to claim 2, wherein the TMV in the package module is aligned or not aligned in the vertical direction.
15. A method for manufacturing an integrated package device, A step of providing a first subpackage module and a second subpackage module, wherein the first subpackage module includes a plurality of first electronic devices and a first molding body that encapsulates the plurality of first electronic devices, each of the first electronic devices including a first pad on its side, and the second subpackage module is located on the side of the first subpackage module, away from the first pad, and includes a plurality of second electronic devices and a second molding body that encapsulates the plurality of second electronic devices, each of the second electronic devices including a second pad on its side; The steps of stacking the first subpackage module and the second subpackage module; A step of forming a first redistribution layer, wherein the first redistribution layer is located on the side of the first subpackage module, away from the second subpackage module, and connected to the first pad; A step of forming a second redistribution layer, wherein the second redistribution layer is located on the side of the second subpackage module, away from the first subpackage module, and is connected to the second pad. Methods that include...
16. A method for manufacturing an integrated package device according to claim 15, wherein the step of forming the second redistribution layer connected to the second pad further includes the step of forming a through-molding via (TMV), the through-molding via (TMV) extending through the first molding body and the second molding body and connecting the first redistribution layer and the second redistribution layer; the second redistribution layer is connected to the TMV.
17. A method for manufacturing an integrated package device according to claim 15 or 16, further comprising the step of forming an external connection structure, wherein the external connection structure is located on the side of the second redistribution layer, away from the second subpackage module, and connected to the second redistribution layer.
18. The step of providing the first subpackage module and the second subpackage module is: The steps include: placing the plurality of first electronic devices and the plurality of second electronic devices on the first temporary adhesive layer and the second temporary adhesive layer, respectively, such that the outer connection surface of the first pad of the first electronic device and the outer connection surface of the second pad of the second electronic device face the same side; A step of arranging a first carrier and a second carrier on the sides of the plurality of first electronic devices and the plurality of second electronic devices, respectively, away from the first temporary adhesive layer and the second temporary adhesive layer, wherein the first carrier and the second carrier each include a temporary bonding film facing the plurality of first electronic devices and the plurality of second electronic devices, and the outer connecting surface of the first pad and the outer connecting surface of the second pad each face the first carrier and the second carrier, respectively, or face away from the first carrier and the second carrier, respectively; The steps include removing the first temporary adhesive layer and the second temporary adhesive layer, and forming the first molding body and the second molding body on the first carrier and the second carrier, respectively. A method for manufacturing the integrated package device according to claim 15, including the following:
19. A method for manufacturing an integrated package device according to claim 18, further comprising the step of arranging a first conductive pillar and a second conductive pillar on a portion of the first pad and a portion of the second pad, respectively, before arranging the first carrier and the second carrier.
20. A method for manufacturing an integrated package device according to claim 15, wherein the step of stacking the first subpackage module and the second subpackage module further includes the step of arranging an adhesive layer between the first subpackage module and the second subpackage module.
21. A method for manufacturing an integrated package device according to claim 15, wherein the step of stacking the first subpackage module and the second subpackage module further includes the step of arranging the first bonding structure and the second bonding structure on the first subpackage module and the second subpackage module, respectively.
22. A method for manufacturing an integrated package device according to claim 15, further comprising the step of forming a protective layer on the side of the first redistribution layer that is separated from the first subpackage module, and covering the first redistribution layer.
23. The steps include: during the step of stacking the first subpackage module and the second subpackage module, the steps of positioning the sides of the first subpackage module and the sides of the second subpackage module, which are separated from the first carrier and the second carrier respectively, so that the first carrier and the second carrier are positioned two outside the combination of the first subpackage module and the second subpackage module, and bringing them closer together; Before forming the first redistribution layer and the second redistribution layer, the first carrier and the second carrier are removed, respectively. A method for manufacturing an integrated package device according to claim 18, further comprising:
24. A method for manufacturing an integrated package device according to claim 17, further comprising the steps of: providing a plurality of the package modules; stacking the plurality of package modules in a direction in which the first subpackage module and the second subpackage module are stacked; and connecting the external connection structure on one of any two adjacent package modules to the first redistribution layer of the other of the two adjacent package modules.
25. A method for manufacturing an integrated package device according to claim 24, comprising the step of stacking the plurality of package modules in the direction in which the first subpackage module and the second subpackage module are stacked, the step of forming a protective layer, wherein the protective layer is positioned on and covers the first redistribution layer of the outermost package module in the vertical direction.
26. Includes an integrated package device according to any one of claims 1 to 14, A memory system in which at least one of the first electronic devices and / or at least one of the second electronic devices in the integrated package device includes a memory device, and at least any other one of the first electronic devices and / or at least any other one of the second electronic devices includes a controller for controlling the operation of the memory device.