垂直堆叠栅极全方位高应变锗纳米线p- fet的首次演示

2018 IEEE Symposium on VLSI Technology Pub Date : 2018-06-01 DOI:10.1109/VLSIT.2018.8510645

E. Capogreco, L. Witters, H. Arimura, F. Sebaai, C. Porret, A. Hikavyy, R. Loo, A. Milenin, G. Eneman, P. Favia, H. Bender, K. Wostyn, E. Litta, A. Schulze, C. Vrancken, A. Opdebeeck, J. Mitard, R. Langer, F. Holsteyns, N. Waldron, K. Barla, V. De Heyn, D. Mocuta, N. Collaert

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引用次数: 11

摘要

本文报道了在300mm SiGe应变松弛缓冲器(SRB)上的应变p型Ge栅极全能(GAA)器件，与我们以前的工作相比，性能有所提高。将Q因子提高到25，在Ioff=100nA/μm时达到了离子=500μA/μm，接近已发表的Ge finfet的最佳结果。还保持了良好的NBTI可靠性。利用开发的单纳米线(NW)工艺流程，首次展示了通道直径为8nm的垂直堆叠应变锗纳米线。对单、双Ge NWs的应变演化进行了系统的分析，首次证明了沿Ge线存在1.7GPa的单轴应力，该应力来源于Ge S/D与Si0.3Ge0.7 SRB之间的晶格失配。

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First demonstration of vertically-stacked Gate-All-Around highly-strained Germanium nanowire p-FETs

This paper reports on strained p-type Ge Gate-All-Around (GAA) devices on 300mm SiGe Strain-Relaxed-Buffers (SRB) with improved performance as compared to our previous work. The Q factor is increased to 25, Ion=500μA/μm at Ioff=100nA/μm is achieved, approaching the best published results on Ge finFETs. Good NBTI reliability is also maintained. By using the process flow developed for the single nanowire (NW), vertically stacked strained Ge NWs featuring 8nm channel diameter are demonstrated for the first time. A systematic analysis of the strain evolution is conducted on both single and double Ge NWs, demonstrating for the first time 1.7GPa uniaxial-stress along the Ge wire, which originates from the lattice mismatch between the Ge S/D and the Si0.3Ge0.7 SRB.

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2018 IEEE Symposium on VLSI Technology

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