高k/金属栅极创新实现持续CMOS缩放

2011 Proceedings of the ESSCIRC (ESSCIRC) Pub Date : 2011-10-13 DOI:10.1109/ESSCIRC.2011.6044913

M. Frank

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引用次数: 29

摘要

高k介电体和金属栅电极已进入互补金属氧化物半导体(CMOS)逻辑技术，集成在门先和门后方案中。我们回顾了栅极优先的高k /金属栅极(HKMG)创新，使器件持续扩展到22和14 nm节点及更高。首先，我们总结了一些允许早期HKMG挑战的见解，例如等效氧化物厚度(EOT)和阈值电压控制。然后，我们讨论了HKMG方法，实现最终的EOT缩放，通过无边界源/漏触点形成的螺距缩放，以及多栅极场效应晶体管的制造。最后，我们总结了高迁移率通道材料(如锗和III-V化合物半导体)栅极堆的最新进展。

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High-k/metal gate innovations enabling continued CMOS scaling

High-k dielectrics and metal gate electrodes have entered complementary metal-oxide-semiconductor (CMOS) logic technology, integrated in both gate-first and gate-last schemes. We review gate-first high-k / metal gate (HKMG) innovations enabling continued device scaling to the 22 and 14 nm nodes and beyond. First, we summarize some of the insight that allowed early HKMG challenges such as equivalent oxide thickness (EOT) and threshold voltage control to be overcome. Then, we discuss HKMG approaches that enable ultimate EOT scaling, pitch scaling via borderless source/drain contact formation, and the fabrication of multi-gate field-effect transistors. Finally, we summarize recent progress in gate stack development for high-mobility channel materials such as germanium and III-V compound semiconductors.

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2011 Proceedings of the ESSCIRC (ESSCIRC)

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