Thermal analysis of GaN HEMTs using nongray multi-speed phonon lattice Boltzmann method under Joule heating effect

IF 1.9 3区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Microelectronics Journal Pub Date : 2024-08-11 DOI:10.1016/j.mejo.2024.106366

Xixin Rao, Yipeng Wu, Kongzhang Huang, Haitao Zhang, Chengdi Xiao

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引用次数: 0

Abstract

Gallium Nitride (GaN) high electron mobility transistors (HEMTs) exhibit superior electrical properties for power and radio frequency applications, but performance is compromised by localized Joule heating, increasing channel temperatures. Precise thermal analysis during design is essential for optimizing device architecture and management strategies. Traditional methods like the Fourier heat diffusion equation (HDE) and the phonon lattice Boltzmann method (PLBM) with the D2Q8 scheme inadequately model phonon ballistic transport at high Knudsen numbers. This study introduces a nongray multi-speed PLBM integrated with the drift-diffusion model to analyze electro-thermal processes in GaN HEMTs. Validated through simulations of thermal conductivities in two-dimensional GaN thin films, the approach examines internal temperature rise in GaN HEMTs under different gate voltages, comparing results with HDE and gray BTE models, and emphasizing the need for non-Fourier effects in thermal analysis. It also evaluates the impact of GaN layer thickness on temperature distribution, providing a robust solution for thermal analysis in GaN HEMTs and other field-effect transistors.

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焦耳加热效应下使用非灰色多速声子晶格玻尔兹曼法对氮化镓 HEMT 进行热分析

氮化镓（GaN）高电子迁移率晶体管（HEMT）在功率和射频应用中表现出卓越的电气性能，但局部焦耳热会导致沟道温度升高，从而影响性能。设计过程中的精确热分析对于优化器件结构和管理策略至关重要。傅立叶热扩散方程 (HDE) 和采用 D2Q8 方案的声子晶格玻尔兹曼法 (PLBM) 等传统方法无法充分模拟高努森数下的声子弹道传输。本研究介绍了一种与漂移扩散模型集成的非灰色多速度 PLBM，用于分析 GaN HEMT 中的电热过程。通过模拟二维氮化镓薄膜的热传导率，该方法检验了氮化镓 HEMT 在不同栅极电压下的内部温升，将结果与 HDE 和灰色 BTE 模型进行了比较，并强调了热分析中非傅里叶效应的必要性。它还评估了氮化镓层厚度对温度分布的影响，为氮化镓 HEMT 和其他场效应晶体管的热分析提供了稳健的解决方案。

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来源期刊

Microelectronics Journal 工程技术-工程：电子与电气

CiteScore

4.00

自引率

27.30%

发文量

222

审稿时长

43 days

期刊介绍： Published since 1969, the Microelectronics Journal is an international forum for the dissemination of research and applications of microelectronic systems, circuits, and emerging technologies. Papers published in the Microelectronics Journal have undergone peer review to ensure originality, relevance, and timeliness. The journal thus provides a worldwide, regular, and comprehensive update on microelectronic circuits and systems. The Microelectronics Journal invites papers describing significant research and applications in all of the areas listed below. Comprehensive review/survey papers covering recent developments will also be considered. The Microelectronics Journal covers circuits and systems. This topic includes but is not limited to: Analog, digital, mixed, and RF circuits and related design methodologies; Logic, architectural, and system level synthesis; Testing, design for testability, built-in self-test; Area, power, and thermal analysis and design; Mixed-domain simulation and design; Embedded systems; Non-von Neumann computing and related technologies and circuits; Design and test of high complexity systems integration; SoC, NoC, SIP, and NIP design and test; 3-D integration design and analysis; Emerging device technologies and circuits, such as FinFETs, SETs, spintronics, SFQ, MTJ, etc. Application aspects such as signal and image processing including circuits for cryptography, sensors, and actuators including sensor networks, reliability and quality issues, and economic models are also welcome.