Ge quantum well channel P-MOSFET for 2.45 GHz wireless weak energy harvesting

IF 2.7 Q2 PHYSICS, CONDENSED MATTER
Yue Wu, Jianjun Song, Ailan Tang, Jianjun Mao
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引用次数: 0

Abstract

Wireless energy harvesting is an important application of microwave wireless energy transmission system, but due to the weak energy of RF signals in the 2.45 GHz band, its rectification efficiency is not ideal. As one of the core rectifier components of wireless weak energy harvesting system, the performance of MOSFET determines the rectification efficiency of the system, and its optimized design to improve the rectification efficiency is an important direction of current research in the field. In view of this, this paper proposes and designs Ge quantum well channel PMOS for wireless weak energy harvesting at 2.45 GHz, aiming to improve the rectification efficiency of wireless weak energy harvesting systems. Starting from adjusting the structural physical parameters of the MOS tubes, the absolute value of the threshold voltage is reduced in the weak energy density region, which in turn improves the rectification efficiency of the device. Then, the novel diode connection with the introduction of substrate bias effect is compared with the conventional connection using an ADS simulation circuit, and the simulation results show that the leakage current is smaller and the rectification efficiency is higher under the novel connection. On this basis, a Ge quantum well channel PMOS device is proposed. Compared with the Ge surface channel, the hole mobility of the quantum well channel will be greatly improved, and its rectification efficiency can also be improved. The device is connected to the rectifier circuit with a novel connection and simulated using Silvaco's Mixedmode module. The results show that the rectification efficiencies of the Ge quantum well channel MOS reach 13.53 % and 32 % at low input powers of −20.34 dBm and −6.28 dBm, respectively, which are 3.3 and 1.14 times higher than those of the conventional surface channel MOS.

用于 2.45 GHz 无线微弱能量采集的 Ge 量子阱沟道 P-MOSFET
无线能量采集是微波无线能量传输系统的重要应用,但由于2.45 GHz频段射频信号能量较弱,其整流效率并不理想。作为无线微弱能量采集系统的核心整流元件之一,MOSFET 的性能决定了系统的整流效率,对其进行优化设计以提高整流效率是当前该领域研究的重要方向。有鉴于此,本文提出并设计了用于 2.45 GHz 无线弱能量收集的 Ge 量子井沟道 PMOS,旨在提高无线弱能量收集系统的整流效率。从调整 MOS 管的结构物理参数入手,降低了弱能量密度区的阈值电压绝对值,从而提高了器件的整流效率。然后,利用 ADS 仿真电路将引入衬底偏压效应的新型二极管连接与传统连接进行了比较,仿真结果表明,新型连接下的漏电流更小,整流效率更高。在此基础上,提出了一种 Ge 量子阱沟道 PMOS 器件。与 Ge 表面沟道相比,量子阱沟道的空穴迁移率将大大提高,其整流效率也能得到改善。该器件采用新颖的连接方式与整流电路相连,并使用 Silvaco 的 Mixedmode 模块进行了仿真。结果表明,在 -20.34 dBm 和 -6.28 dBm 的低输入功率下,Ge 量子阱沟道 MOS 的整流效率分别达到 13.53 % 和 32 %,分别是传统表面沟道 MOS 的 3.3 倍和 1.14 倍。
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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CiteScore
6.50
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