通过缺氧HfOx调制界面层，获得了同时迁移率为412 cm2/V-s, EOT为- 0.5 nm，离子/Ioff为- 105，栅极泄漏为- 10−4 A/cm2的高性能Ge pmosfet

2017 Silicon Nanoelectronics Workshop (SNW) Pub Date : 2017-06-01 DOI:10.23919/SNW.2017.8242272

S. Yi, Jiayi Huang, Chia-Wei Hsu, Tzung-Yu Wu, D. Ruan, K. Chang-Liao

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引用次数: 0

摘要

通过适当的处理，高k/0D-HKVGe02栅极叠加可以同时获得412 cm2/V-sec的峰值空穴迁移率，Vg=Vfb+1 V时极低的Jg(~ 10−4 A/cm2)和0.53 nm的超低EOT。gex层中Ge+1和Ge+2的含量被吸附的氧重新氧化到更高的氧化态，这些氧被OD-HfOx从GeOx中捕获。所提出的栅极堆叠对于Ge MOSFET是有希望的。

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High performance Ge pMOSFETs with simultaneous mobility-412 cm2/V-s, EOT −0.5 nm, Ion/Ioff∼105, gate leakage∼10−4 A/cm2 by modulating interfacial layer using oxygen deficient HfOx

A high peak hole mobility of 412 cm²/V-sec at Ninv=1.8×10¹² cm⁻², a very low Jg of ∼10⁻⁴ A/cm² at Vg=Vfb+1 V and an ultralow EOT of 0.53 nm in Ge pMOSFETs are simultaneously achieved by high-k/0D-HKVGe02 gate stack with suitable treatments. The content of Ge⁺¹ and Ge⁺² in GeOx layer are re-oxidized to higher oxidation state by gettered oxygen, which is captured by OD-HfOx from GeOx. The proposed gate stack is promising for Ge MOSFET.

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2017 Silicon Nanoelectronics Workshop (SNW)

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