Deformation Due to Thermal Source in Micropolar Generalized Thermoelastic Half-Space by Finite Element Method

Abbas, Ibrahim A.; Kumar, Rajneesh

doi:10.1166/jctn.2014.3335

Cited by 43 publications

(17 citation statements)

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“…Lotfy et al [17] investigated the response of a semiconductor medium of variable thermal conductivity due to laser pulses with two temperatures through the photothermal process. Many researchers [18][19][20][21][22][23][24][25][26] have solved various problems under generalized thermoelastic models. In the Laplace domain, the eigenvalues approach gave an analytical solution without any supposed restrictions on the factual physical variables.…”

Section: Introductionmentioning

confidence: 99%

Photo-Thermal Interactions in a Semiconducting Media with a Spherical Cavity under Hyperbolic Two-Temperature Model

Alzahrani

Abbas

2020

Mathematics

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This article highlights the study of photo-thermoelastic interaction in an unbounded semiconductor medium containing a spherical cavity. This problem is solved using the new hyperbolic two-temperature model. The bounding surface of the cavity is traction free and loaded thermally by exponentially decaying pulse boundary heat flux. In addition, the carrier density is prescribed on the inner surface of the cavity in terms of the recombination speed. The techniques of Laplace transforms are used to get the analytical solutions of the problem in the transformed domain by the eigenvalues method. The inversions of Laplace transformations have been carried out numerically. The outcomes also display that the analytical schemes can overcome the mathematical problem to analyze this problem. Numerical outcomes for a semiconductor material are performed and demonstrated graphically. According to the numerical results, this new hyperbolic two-temperature model of thermoelasticity offers finite speed of the thermal wave and mechanical wave propagation.

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Section: Introductionmentioning

confidence: 99%

Photo-Thermal Interactions in a Semiconducting Media with a Spherical Cavity under Hyperbolic Two-Temperature Model

Alzahrani

Abbas

2020

Mathematics

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“…Another priority of this technique is that it allows the visualizing and quantifying of the physical effects, regardless of the experimental limits. The finite element equations of a porothermoelastic problem can be easily obtained by following the standard procedure, as in Abbas et al [35,36]. In the finite element method, the corresponding nodal values of temperatures and displacements can be expressed by the forms…”

Section: Finite Element Methodsmentioning

confidence: 99%

A GL Model on Thermo-Elastic Interaction in a Poroelastic Material Using Finite Element Method

2020

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The purpose of this study is to provide a method to investigate the effects of thermal relaxation times in a poroelastic material by using the finite element method. The formulations are applied under the Green and Lindsay model, with four thermal relaxation times. Due to the complex governing equation, the finite element method has been used to solve these problems. All physical quantities are presented as symmetric and asymmetric tensors. The effects of thermal relaxation times and porosity in a poro-thermoelastic medium are studied. Numerical computations for temperatures, displacements and stresses for the liquid and the solid are presented graphically.

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“…This method is so general that it can be applied to a wide variety of engineering problems including heat transfer, fluid, mechanics, chemical processing etc. For the finite element analysis, one can refer [23][24][25][26][27][28][29][30][31][32][33][34][35]. In the finite element method, the displacement components u, w, and temperature change T are related to the corresponding nodal values by where m denotes the number of nodes per element, and N i are the shape functions.…”

Section: Finite Element Formulationmentioning

confidence: 99%

Thermoelastic interaction in a thermally conducting cubic crystal subjected to ramp-type heating

Abbas

Kumar

Rani

2015

Applied Mathematics and Computation

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Deformation Due to Thermal Source in Micropolar Generalized Thermoelastic Half-Space by Finite Element Method

Cited by 43 publications

References 0 publications

Photo-Thermal Interactions in a Semiconducting Media with a Spherical Cavity under Hyperbolic Two-Temperature Model

Photo-Thermal Interactions in a Semiconducting Media with a Spherical Cavity under Hyperbolic Two-Temperature Model

A GL Model on Thermo-Elastic Interaction in a Poroelastic Material Using Finite Element Method

Thermoelastic interaction in a thermally conducting cubic crystal subjected to ramp-type heating

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