电力电子半导体材料热力学特性的分析研究

IF 2.2 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Zafer Dogan, Tural Mehmetoglu
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引用次数: 0

摘要

理论和实验研究对于准确研究半导体的结构和物理性质至关重要,只有这样,半导体才能在电力电子设备中得到广泛应用。热容量是研究器件材料的电子和电气特性所需的重要热特性。功率电子半导体,如氮化镓、碳化硅、氧化镓和金刚石的比热容,已使用最近开发的爱因斯坦-德贝近似进行了理论评估。根据爱因斯坦-德贝近似法,推导出的热容计算一般分析表达式在整个温度范围内都有效。计算结果与之前可用的实验和理论数据进行了比较,以说明该方法的正确性。评估和文献分析证实了所提方法的有效性。从与文献报道的各种结果的比较中可以看出,这种方法得到的结果既方便又有竞争力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Analytical investigation of thermodynamic properties of power electronic semiconductor materials

Analytical investigation of thermodynamic properties of power electronic semiconductor materials

Theoretical and experimental investigations are critical for accurately investigating the structure and physical properties of semiconductors, allowing their widespread use in power electronic devices. The heat capacities are important thermal properties needed to examine the electronic and electrical properties of device materials. The specific heat capacities of power electronic semiconductors, such as (\({\text{GaN}}\)) gallium nitride, (\({\text{SiC}}\)) silicon carbide, (\({\text{Ga}}_{2} {\text{O}}_{3}\)) gallium oxide, and diamond, have been evaluated theoretically using the recently developed Einstein–Debye approximation. On the grounds of the Einstein–Debye approach, the derived general analytical expression for the calculation of the heat capacities is valid for the entire temperature range. The calculation results are compared with the previously available experimental and theoretical data for illustrating the correctness of the method. The evaluation and literature analysis confirm the effectiveness of the proposed method. As seen from the comparison with various results reported in the literaure, the results obtained from this approach are convenient and competitive.

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来源期刊
Journal of Computational Electronics
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.
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