37 nm栅长PMOS上的凹槽sige漏极扩展可提高35%的驱动电流

Digest of Technical Papers. 2004 Symposium on VLSI Technology, 2004. Pub Date : 2004-06-15 DOI:10.1109/VLSIT.2004.1345386

P. Chidambaram, B. A. Smith, L. Hall, H. Bu, S. Chakravarthi, Y. Kim, A. Samoilov, A. Kim, P.J. Jones, R. B. Irwin, M.J. Kim, A. Rotondaro, C. Machala, D. T. Grider

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引用次数: 82

摘要

本文讨论了目前报道的最佳栅极长度为37 nm (Lg)的PMOS晶体管的结果，该晶体管采用了嵌入式SiGe外延层工艺。过程细节包括在排水扩展(DE)位置成功集成SiGe。高度压缩的SiGe层，靠近通道，导致大的孔迁移率改善。基于HRTEM的晶格参数提取证实了通道中的压缩应变。在SiGe中原位掺杂的B可以比在块状Si中植入的B被激活到更高的程度，从而进一步改善了较低的DE电阻。这两项变化结合起来，PMOS的性能提高了35%，这是前所未有的。过程和设备模拟预测观察到的参数行为，定量地将改进从应力中分离出来/spl / sim/ 28%，从DE电阻中分离出来7%。

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35% drive current improvement from recessed-SiGe drain extensions on 37 nm gate length PMOS

Results from the best reported PMOS transistor at a 37 nm gate length (Lg) built on a process with a recessed SiGe epitaxial layer are discussed. The process details include successful integration of SiGe at the drain extension (DE) location. A highly compressive SiGe layer, in close proximity to the channel, results in large hole mobility improvements. HRTEM based lattice parameter extractions confirm the compressive strain in the channel. In situ doped B in SiGe can be activated to a higher degree than implanted B in bulk Si resulting in further improvements from the lower DE resistance. Both changes combine to give an unprecedented 35% PMOS performance improvement. Process and device simulations that predict the observed parametric behavior quantitatively isolate the improvements to be /spl sim/ 28% from stress and 7% from DE resistance improvement.

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Digest of Technical Papers. 2004 Symposium on VLSI Technology, 2004.

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