Materials challenges for III-V/Si co-integrated CMOS

2015 IEEE Custom Integrated Circuits Conference (CICC) Pub Date : 2015-11-30 DOI:10.1109/CICC.2015.7338398

D. Sadana, C. Cheng, B. Wacaser, W. Spratt, K. Shiu, S. Bedell

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Abstract

This review focuses on material challenges associated with III-V co-integration with Si for future CMOS. There is a huge volume of literature on this topic as implementation of III-V monolithic integration with Si has been the holy grail for last four decades; targeting a wide range of applications including RF devices, LEDs, lasers, photo-detectors and the like. The key drivers have been the cost reduction, scalability with Si wafer diameter, and accessibility to highly scaled integrated circuits next to III-V devices. With the current focus on CMOS the pace of progress on monolithic integration has accelerated by leaps and bounds partly because of its vast impact on CMOS scaling, and partly due to the aggressive CMOS roadmap requirements. The discussion below concentrates on In0.53Ga0.47As channel which is the dominant III-V material being pursued for future technology. Despite the narrow focus, fundamental and engineering challenges posed by this material encompass a broad range of material topics including epitaxial growth, crystallographic defects and their dynamics during growth and subsequent processing, clever device architecture to alleviate adverse impact of defects on device leakage, and innovative engineering for material improvement.

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III-V/Si协积CMOS的材料挑战

这篇综述的重点是与未来CMOS中III-V与Si协整相关的材料挑战。关于这个主题有大量的文献，因为与Si的III-V单片集成的实现在过去四十年中一直是圣杯;针对广泛的应用，包括射频器件，led，激光器，光电探测器等。关键的驱动因素是成本降低，硅晶圆直径的可扩展性，以及III-V器件旁边的高规模集成电路的可访问性。随着目前对CMOS的关注，单片集成的进展速度已经突飞猛进，部分原因是它对CMOS缩放的巨大影响，部分原因是CMOS路线图的激进要求。下面的讨论集中在In0.53Ga0.47As通道，这是未来技术所追求的主要III-V材料。尽管焦点狭窄，但这种材料带来的基础和工程挑战涵盖了广泛的材料主题，包括外延生长，晶体缺陷及其在生长和后续加工过程中的动力学，巧妙的器件结构以减轻缺陷对器件泄漏的不利影响，以及材料改进的创新工程。

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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2015 IEEE Custom Integrated Circuits Conference (CICC)

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