受激变导热非局部半导体圆板介质的光热扩散

IF 1.5 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Advances in Condensed Matter Physics Pub Date : 2023-04-26 DOI:10.1155/2023/1106568

Shreen El-Sapa, K. Lotfy, A. El-Bary, M. H. Ahmed

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引用次数: 0

摘要

为了研究非局部热弹性参数对纳米级半导体材料的影响，本文提出了一种具有变导热系数的非局部模型。在控制方程的框架内利用了化学作用中的光热扩散过程。当弹性波、热波和等离子体波相互作用时，使用非局部连续介质理论来创建该模型。对于得到纳米尺度热光电介质中热应力、位移、载流子密度和温度解析解的主要公式，采用了一维薄圆板的拉普拉斯变换方法。为了产生物理场，在半导体的自由表面施加机械力和热载荷。为了获得研究领域在时-空域上的全解，采用了拉普拉斯变换逆和几种数值逼近技术。在非局部因素的影响下，对主要物理场进行了直观的描述和理论解释。

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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Photo Thermal Diffusion of Excited Nonlocal Semiconductor Circular Plate Medium with Variable Thermal Conductivity

To examine the effects of the nonlocal thermoelastic parameters in a nanoscale semiconductor material, a novel nonlocal model with variable thermal conductivity is provided in this study. The photothermal diffusion (PTD) processes in a chemical action are utilized in the framework of the governing equations. When elastic, thermal, and plasma waves interact, the nonlocal continuum theory is used to create this model. For the main formulations to get the analytical solutions of the thermal stress, displacement, carrier density, and temperature during the nanoscale thermo-photo-electric medium, the Laplace transformation approach in one dimension (1D) of a thin circular plate is utilized. To create the physical fields, mechanical forces and thermal loads are applied to the semiconductor’s free surface. To acquire the full solutions of the research areas in the time-space domains, the inverse of the Laplace transform is applied with several numerical approximation techniques. Under the impact of nonlocal factors, the principal physical fields are visually depicted and theoretically explained.

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来源期刊

Advances in Condensed Matter Physics PHYSICS, CONDENSED MATTER-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Advances in Condensed Matter Physics publishes articles on the experimental and theoretical study of the physics of materials in solid, liquid, amorphous, and exotic states. Papers consider the quantum, classical, and statistical mechanics of materials; their structure, dynamics, and phase transitions; and their magnetic, electronic, thermal, and optical properties. Submission of original research, and focused review articles, is welcomed from researchers from across the entire condensed matter physics community.