Compositionally graded channel HEMTs towards improved linearity for low-noise RF amplifiers

A. Papamichail, Axel R. Persson, Steffen Ricther, P. Kühne, P. O. Persson, M. Thorsell, H. Hjelmgren, N. Rorsman, V. Darakchieva
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Abstract

Although AlGaN/GaN HEMTs with high power and current gain have been demonstrated in RF device applications, at high signal operation they show an inherent non-linear behavior which leads to gain compression and signal distortion. Polarization-doped AlGaN/GaN HEMTs, with a compositionally graded channel enables a linear response improvement through formation of a 3-D electron gas. In this work, we develop the growth process for graded channel HEMTs in a hot-wall MOCVD reactor. Control of the grading profile is established through growth parameter tuning. Afterwards, analysis by EDS allows for precise determination of Al composition across the channel. Conventional and graded channel HEMT structures were fabricated and characterized. Furthermore, the sheet resistance, carrier density and mobility in HEMT structures with different grading profiles are compared and discussed. The conventional (non-graded) structure revealed the highest electron mobility of ~2350 cm2/V.s, which is among the highest values reported.
面向提高低噪声射频放大器线性度的组合渐变通道hemt
尽管具有高功率和高电流增益的AlGaN/GaN hemt已经在射频器件应用中得到了证明,但在高信号操作时,它们表现出固有的非线性行为,导致增益压缩和信号失真。极化掺杂的AlGaN/GaN hemt具有组成渐变的通道,可以通过形成三维电子气体来改善线性响应。在这项工作中,我们开发了梯度通道hemt在热壁MOCVD反应器中的生长过程。分级轮廓的控制是通过生长参数的调整来建立的。然后,通过能谱仪进行分析,可以精确测定整个通道的铝成分。制备了常规和梯度通道HEMT结构并对其进行了表征。此外,还比较和讨论了不同分级结构中薄膜电阻、载流子密度和迁移率。传统(非梯度)结构显示出最高的电子迁移率~2350 cm2/V。S,这是报道的最高值之一。
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