Ultra low p-type SiGe contact resistance FinFETs with Ti silicide liner using cryogenic contact implantation amorphization and Solid-Phase Epitaxial Regrowth (SPER)

2016 IEEE Symposium on VLSI Technology Pub Date : 2016-06-14 DOI:10.1109/VLSIT.2016.7573384

Y. R. Yang, N. Breil, C. Y. Yang, J. Hsieh, F. Chiang, B. Colombeau, B. Guo, K. Shim, N. Variam, G. Leung, J. Hebb, S. Sharma, C. Ni, J. Ren, J. Wen, J. H. Park, H. Chen, S. Chen, M. Hou, D. Tsai, J. Kuo, D. Liao, M. Chudzik, S. H. Lin, H. Huang, N. H. Yang, J. F. Lin, C. Tsai, G. Hung, S. Hsu, O. Cheng, J. Y. Wu, T. Yew

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引用次数: 18

Abstract

We report significant improvement of the TiSi / p-SiGe contact resistance by using a cryogenic (cold) boron implantation technique inside the contact trench of FinFET devices, providing both a source of dopants and a localized amorphization of the source/drain, self-aligned on the contact trench. A record low p-type contact resistivity of 5.9×10-9 ohm-cm2 is demonstrated and a 7.5% performance improvement is achieved. The variation of the implant temperature demonstrates a further improvement of the contact resistance when going to cryogenic (cold) implantation (-100°C). Using TCAD, we demonstrate that the reduced implant temperature provides a higher degree of amorphization and reduces defects. This is the key to provide an enhanced recrystallization of the doped amorphized region through Solid Phase Epitaxial Regrowth (SPER) low temperature activation. We propose in this paper a novel mechanism for p-type contacts, and demonstrate it for the first time on state-of-the-art FinFET p-type devices using cryogenic (cold) implants and SPER regrowth.

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低温接触注入非晶化和固相外延再生(SPER)超低p型SiGe接触电阻硅化钛衬里finfet

通过在FinFET器件的接触沟槽内使用低温(冷)硼注入技术，我们报道了TiSi / p-SiGe接触电阻的显著改善，提供了掺杂剂的来源和源/漏的局部非晶化，在接触沟槽上自对准。p型接触电阻率达到创纪录的5.9×10-9欧姆-平方厘米，性能提高了7.5%。植入体温度的变化表明，当进入低温植入(-100°C)时，接触电阻进一步提高。使用TCAD，我们证明了降低的植入温度提供了更高程度的非晶化和减少缺陷。这是通过固相外延再生(SPER)低温活化提供掺杂非晶区增强再结晶的关键。我们在本文中提出了一种新的p型触点机制，并首次在使用低温(冷)植入和SPER再生的最先进的FinFET p型器件上进行了演示。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 IEEE Symposium on VLSI Technology

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