高密度Cu杂化键合互连的Cu微观结构

Seokho Kim, P. Kang, Taeyeong Kim, Kyuha Lee, Joohee Jang, Kwangjin Moon, Hoonjoo Na, S. Hyun, K. Hwang
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引用次数: 12

摘要

10nm以下半导体器件的微型化面临着更高的工艺难度和更长的开发周期。三维集成电路(3D IC)采用芯片划分和晶圆对晶圆键合已被公认为下一代半导体堆叠技术,因为与相同节点的设备相比,更小的形状,更高的密度集成度和更高的性能。晶圆间键合广泛应用于堆叠式CMOS图像传感器中,即像素与逻辑晶圆之间的键合,该技术具有应用于其他半导体器件的潜力。Cu-Cu杂化键是通过金属(Cu-Cu)和介电材料的晶圆键合实现的。在本研究中,研究了Cu-Cu键合用铜垫经过电镀后和键合后退火后的微观结构。分析了电镀Cu在不同退火温度下的晶粒分布和取向,外加热处理作为焊后工艺。随着高密度键合对焊盘尺寸的要求越来越小,研究了焊盘尺寸和在图案阵列内的位置对Cu微结构的影响。在Cu-Cu成键后,对成键界面进行截面分析,观察Cu原子在相反的Cu衬垫上的相互扩散。将Cu-Cu混合键合应用于240万菊花链试验车上。测量了热应力前后的电阻,证实了Cu-Cu键合界面结构坚固。
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Cu Microstructure of High Density Cu Hybrid Bonding Interconnection
The scaling of semiconductor device below 10nm has faced the higher process difficulty and longer development periods. Three-dimensional integrated circuits (3D IC) using chip partitioning and wafer-to-wafer bonding have been acknowledged as the next generation semiconductor stacking technology because of smaller form factor, higher density integration and higher performance compared to same-node devices. Wafer-to-wafer bonding is widely used in stacked CMOS image sensor, that is, the bonding between pixel and logic wafer, and this technology has the potential to apply other semiconductor devices. Cu-Cu hybrid bonding has achieved by simultaneous wafer bonding of metal (Cu-Cu) and dielectric materials. In this study, it is investigated on the microstructure of Cu pad for Cu-Cu bonding after post-electroplating and post-bonding annealing process. The Cu grain size distribution and orientation are analyzed with different anneal temperature, which is applied on electroplated Cu, and with additional heat treatment as post-bonding process. The effect of pad size as well as the position within pattern array on Cu microstructure is also studied as the bonding pad is required smaller and smaller size for high density bonding. After Cu-Cu bonding, the cross-section analysis of bonding interface is carried out to see inter-diffusion of Cu atoms across the opposite Cu pad. Cu-Cu hybrid bonding is applied to test vehicle having the daisy chain of 2.4 million. The electrical resistance is measured before and after thermal stress and the Cu-Cu bonding interface is confirmed as robust structure.
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