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A comprehensive guide to TSV and other enabling technologies for 3D integration Written by an expert with more than 30 years of experience in the electronics industry, Through-Silicon Vias for 3D Integration provides cutting-edge information on TSV, wafer thinning, thin-wafer handling, microbumping and assembly, and thermal management technologies. Applications to highperformance, high-density, low-power-consumption, wide-bandwidth, and small-form-factor electronic products are discussed. This book offers a timely summary of progress in all aspects of this fascinating field for professionals active in 3D integration research and development, those who wish to master 3D integration problem-solving methods, and anyone in need of a low-power, wide-bandwidth design and high-yield manufacturing process for interconnect systems. Coverage includes: Nanotechnology and 3D integration for the semiconductor industry TSV etching, dielectric-, barrier-, and seed-layer deposition, Cu plating, CMP, and Cu revealing TSVs: mechanical, thermal, and electrical behaviors Thin-wafer strength measurement Wafer thinning and thin-wafer handling Microbumping, assembly, and reliability Microbump electromigration Transient liquid-phase bonding: C2C, C2W, and W2W 2.5D IC integration with interposers 3D IC integration with interposers Thermal management of 3D IC integration 3D IC packaging
A comprehensive guide to TSV and other enabling technologies for 3D integration Written by an expert with more than 30 years of experience in the electronics industry, Through-Silicon Vias for 3D Integration provides cutting-edge information on TSV, wafer thinning, thin-wafer handling, microbumping and assembly, and thermal management technologies. Applications to highperformance, high-density, low-power-consumption, wide-bandwidth, and small-form-factor electronic products are discussed. This book offers a timely summary of progress in all aspects of this fascinating field for professionals active in 3D integration research and development, those who wish to master 3D integration problem-solving methods, and anyone in need of a low-power, wide-bandwidth design and high-yield manufacturing process for interconnect systems. Coverage includes: Nanotechnology and 3D integration for the semiconductor industry TSV etching, dielectric-, barrier-, and seed-layer deposition, Cu plating, CMP, and Cu revealing TSVs: mechanical, thermal, and electrical behaviors Thin-wafer strength measurement Wafer thinning and thin-wafer handling Microbumping, assembly, and reliability Microbump electromigration Transient liquid-phase bonding: C2C, C2W, and W2W 2.5D IC integration with interposers 3D IC integration with interposers Thermal management of 3D IC integration 3D IC packaging
The first encompassing treatise of this new, but very important field puts the known physical limitations for classic 2D electronics into perspective with the requirements for further electronics developments and market necessities. This two-volume handbook presents 3D solutions to the feature density problem, addressing all important issues, such as wafer processing, die bonding, packaging technology, and thermal aspects. It begins with an introductory part, which defines necessary goals, existing issues and relates 3D integration to the semiconductor roadmap of the industry. Before going on to cover processing technology and 3D structure fabrication strategies in detail. This is followed by fields of application and a look at the future of 3D integration. The contributions come from key players in the field, from both academia and industry, including such companies as Lincoln Labs, Fraunhofer, RPI, ASET, IMEC, CEA-LETI, IBM, and Renesas.
This book focuses on foundry-based process technology that enables the fabrication of 3-D ICs. The core of the book discusses the technology platform for pre-packaging wafer lever 3-D ICs. However, this book does not include a detailed discussion of 3-D ICs design and 3-D packaging. This is an edited book based on chapters contributed by various experts in the field of wafer-level 3-D ICs process technology. They are from academia, research labs and industry.
A comprehensive guide to 3D IC integration and packaging technology3D IC Integration and Packaging fully explains the latest microelectronics techniques for increasing chip density and maximizing performance while reducing power consumption. Based on a course developed by its author, this practical guide offers real-world problem-solving methods and teaches the trade-offs inherent in making system-level decisions. Explore key enabling technologies such as TSV, thin-wafer strength measurement and handling, microsolder bumping, redistribution layers, interposers, wafer-to-wafer bonding, chip-to-wafer bonding, 3D IC and MEMS, LED, and complementary metal-oxide semiconductor image sensors integration. Assembly, thermal management, and reliability are covered in complete detail.3D IC Integration and Packaging covers:• 3D integration for semiconductor IC packaging• Through-silicon vias modeling and testing• Stress sensors for thin-wafer handling and strength measurement• Package substrate technologies• Microbump fabrication, assembly, and reliability• 3D Si integration• 2.5D/3D IC integration• 3D IC integration with passive interposer• Thermal management of 2.5D/3D IC integration• Embedded 3D hybrid integration• 3D LED and IC integration• 3D MEMS and IC integration• 3D CMOS image sensors and IC integration• PoP, chip-to-chip interconnects, and embedded fan-out WLP
Three-dimensional (3D) integrated circuit (IC) stacking is the next big step in electronic system integration. It enables packing more functionality, as well as integration of heterogeneous materials, devices, and signals, in the same space (volume). This results in consumer electronics (e.g., mobile, handheld devices) which can run more powerful applications, such as full-length movies and 3D games, with longer battery life. This technology is so promising that it is expected to be a mainstream technology a few years from now, less than 10-15 years from its original conception. To achieve this type of end product, changes in the entire manufacturing and design process of electronic systems are taking place. This book provides readers with an accessible tutorial on a broad range of topics essential to the non-expert in 3D System Integration. It is an invaluable resource for anybody in need of an overview of the 3D manufacturing and design chain.
This book presents a realistic and a holistic review of the microelectronic and semiconductor technology options in the post Moore’s Law regime. Technical tradeoffs, from architecture down to manufacturing processes, associated with the 2.5D and 3D integration technologies, as well as the business and product management considerations encountered when faced by disruptive technology options, are presented. Coverage includes a discussion of Integrated Device Manufacturer (IDM) vs Fabless, vs Foundry, and Outsourced Assembly and Test (OSAT) barriers to implementation of disruptive technology options. This book is a must-read for any IC product team that is considering getting off the Moore’s Law track, and leveraging some of the More-than-Moore technology options for their next microelectronic product.
Discover an up-to-date exploration of Embedded and Fan-Out Waver and Panel Level technologies In Embedded and Fan-Out Wafer and Panel Level Packaging Technologies for Advanced Application Spaces: High Performance Compute and System-in-Package, a team of accomplished semiconductor experts delivers an in-depth treatment of various fan-out and embedded die approaches. The book begins with a market analysis of the latest technology trends in Fan-Out and Wafer Level Packaging before moving on to a cost analysis of these solutions. The contributors discuss the new package types for advanced application spaces being created by companies like TSMC, Deca Technologies, and ASE Group. Finally, emerging technologies from academia are explored. Embedded and Fan-Out Wafer and Panel Level Packaging Technologies for Advanced Application Spaces is an indispensable resource for microelectronic package engineers, managers, and decision makers working with OEMs and IDMs. It is also a must-read for professors and graduate students working in microelectronics packaging research.
The first encompassing treatise of this new and very important field puts the known physical limitations for classic 2D microelectronics into perspective with the requirements for further microelectronics developments and market necessities. This two-volume handbook presents 3D solutions to the feature density problem, addressing all important issues, such as wafer processing, die bonding, packaging technology, and thermal aspects. It begins with an introductory part, which defines necessary goals, existing issues and relates 3D integration to the semiconductor roadmap of the industry. Before going on to cover processing technology and 3D structure fabrication strategies in detail. This is followed by fields of application and a look at the future of 3D integration. The editors have assembled contributions from key academic and industrial players in the field, including Intel, Micron, IBM, Infineon, Qimonda, NXP, Philips, Toshiba, Semitool, EVG, Tezzaron, Lincoln Labs, Fraunhofer, RPI, IMEC, CEA-LETI and many others.
Strain Effect in Semiconductors: Theory and Device Applications presents the fundamentals and applications of strain in semiconductors and semiconductor devices that is relevant for strain-enhanced advanced CMOS technology and strain-based piezoresistive MEMS transducers. Discusses relevant applications of strain while also focusing on the fundamental physics pertaining to bulk, planar, and scaled nano-devices. Hence, this book is relevant for current strained Si logic technology as well as for understanding the physics and scaling for future strained nano-scale devices.