Electrothermal properties of 2D materials in device applications

IF 2.2 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Computational Electronics Pub Date : 2023-09-26 DOI:10.1007/s10825-023-02091-z

Samantha Klein, Zlatan Aksamija

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引用次数: 0

Abstract

To continue downscaling transistors, new materials must be explored. Two-dimensional (2D) materials are appealing due to their thinness and bandgap. The relatively weak van der Waals forces between layers in 2D materials allow easy exfoliation and device fabrication but also result in poor heat transfer between layers and to the substrate, which is the main path for heat removal, resulting in self-heating and thermal degradation of mobility. This study explores the electrothermal properties of five popular 2D materials (MoS₂, MoSe₂, WS₂, WSe₂, and 2D black phosphorous). We simulate various devices with self-heating with a range of gate and drain biases and examine the effects on mobility and change in device temperature. The effects are compared to the isothermal case to ascertain the impact of self-heating. We observe that Joule heating has a significant effect on temperature rise, layerwise drain current, and effective mobility. We show that black phosphorous performs the best thermally, owing to its relatively high thermal conductance to the substrate, while WSe₂ performs the best electrically. This study will inform future thermally aware designs of nanoelectronic devices based on 2D materials.

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器件应用中二维材料的电热特性

为了继续缩小晶体管的规模，必须探索新的材料。二维（2D）材料由于其薄和带隙而具有吸引力。在2D材料中，层之间相对较弱的范德华力允许容易剥离和器件制造，但也会导致层之间和基板之间的热传递较差，基板是除热的主要路径，导致自加热和迁移率的热降解。本研究探讨了五种流行的2D材料（MoS2、MoSe2、WS2、WSe2和2D黑磷）的电热特性。我们模拟了具有一定范围的栅极和漏极偏置的自加热的各种器件，并研究了对迁移率和器件温度变化的影响。将这些影响与等温情况进行比较，以确定自加热的影响。我们观察到焦耳加热对温度上升、层漏电流和有效迁移率有显著影响。我们发现，由于黑磷对衬底的导热性相对较高，因此其热性能最好，而WSe2的电学性能最好。这项研究将为未来基于2D材料的纳米电子器件的热感知设计提供信息。

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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来源期刊

Journal of Computational Electronics ENGINEERING, ELECTRICAL & ELECTRONIC-PHYSICS, APPLIED

CiteScore

4.50

自引率

4.80%

发文量

142

审稿时长

>12 weeks

期刊介绍： he Journal of Computational Electronics brings together research on all aspects of modeling and simulation of modern electronics. This includes optical, electronic, mechanical, and quantum mechanical aspects, as well as research on the underlying mathematical algorithms and computational details. The related areas of energy conversion/storage and of molecular and biological systems, in which the thrust is on the charge transport, electronic, mechanical, and optical properties, are also covered. In particular, we encourage manuscripts dealing with device simulation; with optical and optoelectronic systems and photonics; with energy storage (e.g. batteries, fuel cells) and harvesting (e.g. photovoltaic), with simulation of circuits, VLSI layout, logic and architecture (based on, for example, CMOS devices, quantum-cellular automata, QBITs, or single-electron transistors); with electromagnetic simulations (such as microwave electronics and components); or with molecular and biological systems. However, in all these cases, the submitted manuscripts should explicitly address the electronic properties of the relevant systems, materials, or devices and/or present novel contributions to the physical models, computational strategies, or numerical algorithms.