二维电子漂移引起的声功率增益

Lei Shao, K. Pipe
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引用次数: 1

摘要

本文分析了纳米尺度二维电子气体中电子漂移对表面声波的放大作用。我们比较了电子漂移在大块GaN薄膜层和基于GaN的2DEG层中产生的每个SAW弧度的声功率增益量。计算表明,在2DEG中的声放大与声SAW频率无关,而只有非常窄的带宽的声SAW可以被大量放大。此外,每个SAW弧度的峰值功率增益发生在一个更实用的载流子密度下,对于2g比对于块状材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Acoustic power gain induced by 2D electron drifting
In this work, amplification of surface acoustic waves (SAWs) by electron drift in a nanometer-scale two-dimensional electron gas (2DEG) is analyzed analytically. We compare the amount of acoustic power gain per SAW radian produced by electron drift in a bulk GaN thin film layer and in a GaN-based 2DEG layer. Calculations suggest that acoustic amplification in a 2DEG is independent on the SAW frequency while only a very narrow bandwidth of SAWs could be amplified in bulk. Furthermore, the peak power gain per SAW radian occurs at a more practical carrier density for a 2DEG than for a bulk material.
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