互连
倒装芯片
电介质
材料科学
反向
沉积(地质)
引线键合
阳极连接
过程(计算)
过程集成
电子工程
集成电路
纳米尺度
热的
灵敏度(控制系统)
热压连接
粘接
集成电路封装
光电子学
工作(物理)
表征(材料科学)
成套系统
纳米技术
硅
作者
Madison Manley,Rohan Sahay,Dipayan Pal,Ashita Victor,Danish Baig,Jit Dutta,Andrew C. Kummel,Muhannad S. Bakir
出处
期刊:IEEE Transactions on Components, Packaging and Manufacturing Technology
[Institute of Electrical and Electronics Engineers]
日期:2026-01-05
卷期号:16 (2): 455-457
标识
DOI:10.1109/tcpmt.2026.3650893
摘要
Interconnect technologies are critical to meet the electrical and thermal requirements for high-performance heterogeneous integration systems. This work presents inverse hybrid bonding (IHB), a die-to-die/die-to-wafer (D2D/D2W) bonding technology for heterogeneous integration that enables optimized interconnect designs, process flexibility, and a batch scale “underfill” that employs a gas-phase deposition process for dielectric underfill. It is “inverse” because the metal-metal bonding occurs first; subsequently, the dielectric underfill improves the mechanical reliability. To demonstrate IHB, copper-copper (Cu-Cu) thermal compression bonding (TCB) is first used for electrical connectivity, followed by a vapor-phase deposition of metal organic framework (MOF) for dielectric underfill. A detailed study of the process parameters for the MOF deposition process and its effect on underfill coverage is presented. IHB is demonstrated on an electrical testbed that features simultaneous bonding of fine-pitch (20 μm) and large-pitch (100 μm) interconnects, demonstrating true heterogeneous integration. Compared to solder-based technologies and hybrid bonding, IHB is a simplified D2D/D2W process that enables interconnect design flexibility, a batch scale underfill process that is not constrained by legacy underfills, and reduced process sensitivity to surface particles and roughness.
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