High Gain 220 - 275 GHz Amplifier MMICs Based on Metamorphic 20 nm InGaAs MOSFET Technology

2018 IEEE BiCMOS and Compound Semiconductor Integrated Circuits and Technology Symposium (BCICTS) Pub Date : 2018-10-01 DOI:10.1109/BCICTS.2018.8550836

A. Tessmann, A. Leuther, F. Heinz, F. Bernhardt, H. Massler

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引用次数: 2

Abstract

Compact high gain 220 to 275 GHz millimeter wave monolithic integrated circuit (MMIC) amplifiers have been developed, based on a metamorphic 20 nm gate length InGaAs metal-oxide-semiconductor field-effect transistor (MOSFET) technology. Therefore, an Al2O3/HfO2layer stack was deposited as a gate dielectric directly on top of an $\mathbf{In}_{0.8}\mathbf{Ga}_{0.2}\mathbf{As}$ channel by atomic layer deposition. The gate layout was optimized for millimeter wave and submillimeter wave integrated circuit applications using T-gates and wet chemical recess etching to minimize the parasitic gate capacitances. For a $2\times 10\ \mu \text{m}$ gate width transistor, a transit frequency $f_{\text{T}}$ of 275 GHz and a record maximum oscillation frequency $f_{max}$ of 640 GHz was extrapolated. A realized three-stage cascode amplifier circuit demonstrated a maximum gain of 21 dB at 263 GHz and a small-signal gain of more than 18 dB between 222 and 274 GHz. The total chip size of the millimeter wave amplifier MMIC was only $0.5\times 1.2\ \mathbf{mm}^{2}$.

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基于20纳米InGaAs MOSFET技术的高增益220 - 275 GHz放大器mmic

基于20 nm栅长InGaAs金属氧化物半导体场效应晶体管(MOSFET)技术，研制了一种紧凑的高增益220 ~ 275 GHz毫米波单片集成电路(MMIC)放大器。因此，在$\mathbf{In}_{0.8}\mathbf{Ga}_{0.2}\mathbf{as}$通道上直接沉积了Al2O3/ hfo2层作为栅极电介质。采用t型栅极和湿化学凹槽蚀刻技术，优化了毫米波和亚毫米波集成电路的栅极布局，以最小化寄生栅极电容。对于2\ \ × 10\ \ \mu \text{m}$栅极宽度晶体管，推断出传输频率$f_{\text{T}}$为275 GHz，最大振荡频率$f_{max}$为640 GHz。所实现的三级级联放大器电路在263ghz时的最大增益为21db，在222 ~ 274ghz之间的小信号增益大于18db。毫米波放大器MMIC的总芯片尺寸仅为$0.5\乘以1.2\ \mathbf{mm}^{2}$。

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2018 IEEE BiCMOS and Compound Semiconductor Integrated Circuits and Technology Symposium (BCICTS)

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