ABSTRACT

The overlapping between the initial magnetic field and the generalized thermoelasticity theory during the excited semiconductor medium is studied. The microtemperature process in the context of the photothermal theory (due to the thermal effect) is obtained for the main fields of a rotator medium. The disturbances of the elastic-plasma-thermal waves are investigated in two-dimensional (2D) deformation. The governing equations are discussed in the Fourier and Laplace domains when microelements possess microtemperatures. The basic analytical solutions of the main variables are constructed with Laplace transform. The boundary conditions as well as mechanical ramp and isothermal type are applied on the outer surface of the semiconductor elastic medium to obtain the unknown parameters. The complete solutions of the main variables field in the space-time domain are observed when the inversion techniques are used numerically. The effects of parameters of rotation, thermoelectric coupling, and magnetic field are discussed theoretically and graphically in 2D and 3D.

摘要

研究了激发半导体介质过程中初始磁场与广义热弹性理论的重叠。针对旋转介质的主要场获得了光热理论（由于热效应）背景下的微温过程。在二维 (2D) 变形中研究了弹性等离子体热波的扰动。当微元件具有微温时，控制方程在傅立叶域和拉普拉斯域中进行了讨论。主要变量的基本解析解采用拉普拉斯变换构造。边界条件以及机械斜坡和等温类型应用于半导体弹性介质的外表面以获得未知参数。在数值上使用反演技术时，观察到时空域主变量场的完全解。以 2D 和 3D 理论和图形方式讨论了旋转、热电耦合和磁场参数的影响。