Pulsed Laser-Induced Single-Event Transients in InGaAs FinFETs with sub-10-nm Fin Widths

2019 19th European Conference on Radiation and Its Effects on Components and Systems (RADECS) Pub Date : 2019-09-01 DOI:10.1109/radecs47380.2019.9745711

Kan Li, E. Zhang, S. Bonaldo, A. Sternberg, J. Kozub, Andrew M. Tonigan, M. Reaz, L. Ryder, Kaitlyn L. Ryder, H. Gong, S. Weiss, R. Weller, A. Vardi, J. D. del Alamo, R. Reed, D. Fleetwood, peixiong zhao

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引用次数: 1

Abstract

The single-event transient (SET) response and charge collection mechanisms are investigated for InGaAs FinFETs on InP substrates with sub-10-nm fin widths through pulsed laser irradiation. The dependences on fin width, $V_{DS}$ and $V_{GS}$ are examined. Consistent with devices with fin widths larger than 10 nm, higher transient peak and greater charge collection are observed in wider fin devices as a result of larger active volumes. The amplitude of the SET and the collected charge also increase with $V_{DS}$ due to the enhancement of electric field along the channel, and decrease as the overdrive voltage increases due to the reduced excess electron density. Charge collection is influenced strongly by the shunt effect from source-to-drain when the laser spot covers the channel region, and the parasitic bipolar effect caused by accumulated holes underneath the channel.

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亚10nm鳍宽InGaAs finfet的脉冲激光诱导单事件瞬态

研究了脉冲激光辐照下鳍宽小于10 nm的InP衬底InGaAs finfet的单事件瞬态(SET)响应和电荷收集机制。对翅片宽度、$V_{DS}$和$V_{GS}$的依赖关系进行了分析。与翅片宽度大于10 nm的器件一致，由于更大的有源体积，在更宽的鳍片器件中观察到更高的瞬态峰和更大的电荷收集。由于电场沿通道的增强，SET和电荷的振幅也随着V_{DS}$的增大而增大，由于过量电子密度的减小而随着超速电压的增大而减小。当激光光斑覆盖通道区域时，从源极到漏极的分流效应和通道下方积累的空穴引起的寄生双极效应对电荷收集有强烈的影响。

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2019 19th European Conference on Radiation and Its Effects on Components and Systems (RADECS)

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