Impact of Temperature and Trap Charges on Heterojunction Tunnel FET

2020 National Conference on Emerging Trends on Sustainable Technology and Engineering Applications (NCETSTEA) Pub Date : 2020-02-01 DOI:10.1109/NCETSTEA48365.2020.9119953

D. Das, Raju Pandey, S. Baishya, U. Chakraborty

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Abstract

In this article, a comprehensive comparison of Si-SiGe hetero-junction tunnel field effect transistor (TFET) and conventional TFET is presented. The Silicon-Germanium (SiGe) pocket utilized in the proposed TFET structure reduces the tunneling distance to provide enhanced ON current as compared to the conventional one. Moreover, the proposed heterojunction TFET offers super-steeper sub-threshold swing (SS) of 14 mV/dec. The temperature dependence characteristics and its impact on interface traps for both the structures are explored and examined. Results expose that TFET shows less temperature dependence in the ON state due to band to band tunneling mechanism of current conduction. While, in the OFF state the temperature dependency is increased. It is found that the TFET has less effect of interface traps on ON current degradation than leakage current. It is also found that the proposed hetero-junction TFET shows better immunity against trap effect even under temperature variation as compared to the conventional TFET. This confirms the superiority and reliability of the proposed hetero-junction TFET for recent semiconductor industries.

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温度和陷阱电荷对异质结隧道场效应管的影响

本文对Si-SiGe异质结隧道场效应晶体管(ttfet)和传统的ttfet进行了全面的比较。与传统结构相比，该结构中使用的硅锗(SiGe)口袋减少了隧道距离，提供了增强的ON电流。此外，所提出的异质结TFET具有14 mV/dec的超陡亚阈值摆幅(SS)。研究了这两种结构的温度依赖特性及其对界面陷阱的影响。结果表明，由于电流传导的带间隧道机制，TFET在导通状态下表现出较小的温度依赖性。而在OFF状态下，温度依赖性增加。发现界面陷阱对晶体管导通电流退化的影响小于漏电流。在温度变化的情况下，异质结TFET对陷阱效应的免疫性能优于传统的TFET。这证实了所提出的异质结TFET在最近半导体工业中的优越性和可靠性。

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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2020 National Conference on Emerging Trends on Sustainable Technology and Engineering Applications (NCETSTEA)

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