First Demonstration of heterogenous Complementary FETs utilizing Low-Temperature (200 °C) Hetero-Layers Bonding Technique (LT-HBT)

T. Z. Hong,W.-H. Chang,A. Agarwal,Y. T. Huang,C.-Y. Yang,T-Y. Chu,H.-Y. Chao,Y. Chuang,S.T. Chung,J. H. Lin,S.M. Luo,C.-J. Tsai,M. J. Li,X.-R. Yu,N.-C. Lin,Ta-Chun Cho,Po-Jung Sung,C J Su,G. L. Luo,Fu-Kuo Hsueh,Kun Lin Lin,Hiroyuki Ishii,Toshifumi Irisawa,Tatsuro Maeda,C. T. Wu,W. C.-Y. Ma,Darsen D. Lu,Kuo-Hsing Kao,Yao-Jen Lee,Hisu Chih Chen,Chia-Min Lin,R. W. Chuang,K.P. Huang,Seiji Samukawa,Yiming Li,J.H. Tarng,Tien-Sheng Chao,Makoto Miura,Guo-Wei Huang,W-F Wu,Jiun-Yun Li,J.-M. Shieh,Yeong Her Wang,Wen-Kuan Yeh

First Demonstration of heterogenous Complementary FETs utilizing Low-Temperature (200 °C) Hetero-Layers Bonding Technique (LT-HBT)

2020

For the first time, we demonstrate heterogeneous complementary FETs (hCFETs) with Ge and Si channels fabricated with a layer transfer technique. The 3D channel stacking integration particularly employs a low-temperature (200 °C) hetero-layers bonding technique (LT-HBT) realized by a surface activating chemical treatment at room temperature, enabling Ge channels bonded onto Si wafers. Furthermore, to obtain symmetric performance in n/p FETs, a multi-channel structure of two-channel Si and one-channel Ge is also implemented. Wafer-scale LT-HBT is demonstrated successfully, showing new opportunities for the ultimate device footprint scaling with heterogeneous integration.

Keywords:

Wafer
layer
Heterojunction bipolar transistor
Thermal stability
Silicon
Optoelectronics
Field-effect transistor
Stacking
Germanium
Materials science

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