1- 10ghz接口设计的SiN/sub //InP/InGaAs HIGFET技术

Proceedings of 8th International Conference on Indium Phosphide and Related Materials Pub Date : 1996-04-21 DOI:10.1109/ICIPRM.1996.492389

C.S. Sundararaman, M. Tazlauanu, P. Mihelich, A. Bensaada, R. Masut

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引用次数: 0

摘要

本文描述了一种独特的接口控制层(ICL) SiN/sub x//lnP/InGaAs异质结绝缘栅(HIG)场效应管技术的发展历程。采用一种新型的光电化学方法制备了In-S单层ICL，用于降低和控制SiN/sub x//InP界面上的阱态。使用这种方法制造的埋道绝缘栅ICL higfet工作在大栅极电压范围内(V/sub /=/spl plusmn/ 8v)，极低的栅极漏电(10 nA@V/sub /=/spl plusmn/ 5v)， I/sub /(sat)为250 mA/mm。未掺杂的沟道ICL higfet表现出40 mS/mm的跨导(g/sub /m /)，这受到通过缓冲层传导的限制。通过使用掺杂InGaAs通道并消除通过器件的平行传导路径，实现了g/sub m/ (140-150 mS/mm)的3至4倍改善。掺杂通道higfet的f/sub t/为5-6 GHz (Lg=3 /spl mu/m)， f/sub max/为10-12 GHz，在3 GHz时功率增益为14.2 dB。ICL HIGFET技术已被用于构建简单的电路，例如在3ghz频率下增益为7- 10db的缓冲放大器，以及最近在2ghz频率下工作的高频采样和保持ICL HIGFET电路。

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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A 1-10 GHz interface engineered SiN/sub x//InP/InGaAs HIGFET technology

The evolution of an unique interface control layer (ICL) SiN/sub x//lnP/InGaAs Heterojunction Insulated Gate (HIG)FET technology is described from its inception. An In-S monolayer ICL, formed by a novel photoelectrochemical process, is used to reduce and control trap states at the SiN/sub x//InP interface. Buried channel insulated gate ICL HIGFETs fabricated using this approach operate over a large gate voltage range (V/sub gs/=/spl plusmn/8 V) with very low gate leakage (10 nA@V/sub gs/=/spl plusmn/5 V) and I/sub ds/(sat) of 250 mA/mm. Undoped channel ICL HIGFETs exhibit transconductance (g/sub m/) of 40 mS/mm that is limited by conduction through the buffer layer. A 3 to 4 fold improvement in g/sub m/ (140-150 mS/mm) is achieved by using a doped InGaAs channel and eliminating parallel conduction paths through the device. The doped channel HIGFETs show f/sub t/ of 5-6 GHz (Lg=3 /spl mu/m) and f/sub max/ of 10-12 GHz with a power gain of 14.2 dB at 3 GHz. The ICL HIGFET technology has been used to construct simple circuits such as buffer amplifiers with a gain of 7-10 dB at 3 GHz and recently, high frequency sample and hold ICL HIGFET circuits that operate at frequencies of 2 GHz.

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Proceedings of 8th International Conference on Indium Phosphide and Related Materials

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