Y. Yeo, X. Gong, M. V. van Dal, G. Vellianitis, M. Passlack
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引用次数: 28
摘要
在未来的晶体管中,高迁移率沟道材料可以取代应变硅,以提高速度性能和/或降低功耗。在普通元素和化合物半导体中,Ge的空穴迁移率最高,其电子迁移率是Si的两倍。因此,Ge是未来CMOS的一种很有前途的通道材料(图1)。主要挑战包括在可制造工艺中经济高效地集成Ge on Si,在大规模的eot上为n-和p- fet形成高质量的栅极堆,提供高通道迁移率,以及与小带隙相关的泄漏问题。本文讨论了推进ge基晶体管技术的最新研究进展。将讨论Ge在Si衬底上的集成,以实现高性能器件的制造,并形成用于Ge fet(特别是n- fet)的高质量栅极堆栈。我们还探索了提高Ge迁移率的机会,例如将Sn掺入Ge中形成Ge1-xSnx。此外,通过提高Sn的组成,Ge1-xSnx的带隙EG变小,并从间接过渡到直接,使Ge1-xSnx成为一种有前途的隧道晶体管材料。
Germanium-based transistors for future high performance and low power logic applications
High mobility channel materials could replace strained Si to enhance speed performance and/or reduce power consumption in future transistors. Ge has the highest hole mobility among common elemental and compound semiconductors, and an electron mobility that is two times larger than that of Si. Ge is thus a promising channel material for future CMOS (Fig. 1). Key challenges include cost-effective integration of Ge on Si in a manufacturable process, formation of high-quality gate stack on Ge for n- and p-FETs at aggressively scaled EOTs that deliver high channel mobilities, and leakage issues related to its small bandgap. In this paper, we discuss recent research progress in advancing Ge-based transistor technologies. Integration of Ge on Si substrate to enable fabrication of high performance devices and formation of high-quality gate stack for Ge FETs (particularly for n-FETs) will be discussed. We also explore opportunities to boost the mobility of Ge, e.g. by incorporating Sn in Ge to form Ge1-xSnx. Furthermore, by raising the Sn composition, the band gap EG of Ge1-xSnx becomes smaller and transits from indirect to direct, making Ge1-xSnx a promising material for tunneling transistors.
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