亚微米氧化镓射频场效应晶体管

2018 IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP) Pub Date : 2018-07-01 DOI:10.1109/IMWS-AMP.2018.8457153

K. Chabak, D. Walker, A. Green, A. Crespo, M. Lindquist, K. Leedy, S. Tetlak, R. Gilbert, N. Moser, G. Jessen

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引用次数: 29

摘要

采用亚微米t形栅极，研究了β -氧化镓(BGO)射频器件的性能。在第一个设计中，实现了一个门凹槽以允许门和通道器件缩放，从而导致$\text{f}_{\mathbf {t}} {/\mathbf {f}} _{\mathbf {max}} \quad =$ 3/13 GHz， $\text{V}_{\mathbf {DS}} \quad =$ 40 V。第二种方法是使用一个薄的高掺杂通道和一个由电子束光刻形成的t栅。$\text{f}_{\mathbf {t}} {/\mathbf {f}} _{\mathbf {max}} \quad =$ 5/17 GHz的测量值为${V}_{DS} =$ 15 V，是BGO晶体管中报道的最高电压。随着器件寄生和垂直扩展外延设计的减少，射频性能有望显著提高。

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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Sub-Micron Gallium Oxide Radio Frequency Field-Effect Transistors

Beta-gallium oxide (BGO) radio frequency device performance is presented using sub-micron T-shaped gates. In the first design, a gate-recess is implemented to allow gate and channel device scaling which results in $\text{f}_{\mathbf {t}} {/\mathbf {f}} _{\mathbf {max}} \quad =$ 3/13 GHz at $\text{V}_{\mathbf {DS}} \quad =$ 40 V. The second approach uses a thin and higher doped channel with a T-gate formed by electron beam lithography. An $\text{f}_{\mathbf {t}} {/\mathbf {f}} _{\mathbf {max}} \quad =$ 5/17 GHz is measured at ${V}_{DS} =$ 15 V and is the highest reported for BGO transistors. Significant gains in RF performance are expected with reduction of device parasitics and vertically scaled epitaxial designs.

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2018 IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP)

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