基于非对称纳米环场效应管的破纪录高性能太赫兹成像技术

2019 Symposium on VLSI Technology Pub Date : 2019-06-01 DOI:10.23919/VLSIT.2019.8776567

E. Jang, M. Ryu, R. Patel, S. H. Ahn, H. J. Jeon, K. Han, K. R. Kim

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引用次数: 3

摘要

我们在等离子体太赫兹(THz)探测器领域展示了一种使用65纳米CMOS代工厂的创纪录高性能单片天线(晶体管天线)。通过将源极和漏极之间的最终结构不对称应用于源极直径$(d_{\text{S}})$从30缩放到$0.37\mu \text{m}$的环形场效应管，我们在片上太赫兹测量中获得了180倍的光响应增强$(\Delta u)$。通过自由空间太赫兹成像实验，环形场效应管的导电漏极区本身在$0.09\sim 0.2$太赫兹范围内谐振频率为0.12太赫兹，具有与极化无关的各向同性圆形天线成像结果。高度可扩展和无馈线的单片天线使高性能太赫兹探测器在目标频率下的响应率为8.8 kV/ $W$和NEP为$3.36\text{pW}/\text{Hz}^{05}$。

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Record-High Performance Trantenna based on Asymmetric Nano-Ring FET for Polarization-Independent Large-Scale/Real-Time THz Imaging

We demonstrate a record-high performance monolithic trantenna (transistor-antenna) using 65-nm CMOS foundry in the field of a plasmonic terahertz (THz) detector. By applying ultimate structural asymmetry between source and drain on a ring FET with source diameter $(d_{\text{S}})$ scaling from 30 to $0.37\mu \text{m}$, we obtained 180 times more enhanced photoresponse $(\Delta u)$ in on-chip THz measurement. Through free-space THz imaging experiments, the conductive drain region of ring FET itself showed a frequency sensitivity with resonance frequency at 0.12 THz in $0.09\sim 0.2$ THz range and polarization-independent imaging results as an isotropic circular antenna. Highly-scalable and feeding line-free monolithic trantenna enables a high-performance THz detector with responsivity of 8.8 kV/$W$ and NEP of $3.36\text{pW}/\text{Hz}^{05}$ at the target frequency.

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2019 Symposium on VLSI Technology

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