A One-dimensional Model of Thermo-electroelasticity in Extended Thermodynamics

Abou-Dina, M. S.; Ghaleb, A. F.

doi:10.24200/squjs.vol23iss1pp1-7

Cited by 3 publications

(2 citation statements)

References 15 publications

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“…The delay shown in the gures below concerning the displacement, temperature and heat ux will be somewhat dierent due to the fact that the speed is not exactly equal to v e according to (27).…”

Section: Dimension Analysismentioning

confidence: 99%

“…This fully nonlinear model involves a multitude of quadratic couplings, and was formulated in material coordinates, a fact that makes the resulting equations useful for the investigation of cases where the electrodes are attached to the medium. Simplied versions for thermoelasticity and for thermo-electroelasticity were investigated in [26,27]. Chirilȃ et al [28] developed a thermo-electro-mechanical continuum theory for biomedical purposes following a Green-Naghdi approach to thermodynamics.…”

Section: Introductionmentioning

confidence: 99%

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One-dimensional nonlinear model of generalized thermo-electroelasticity

Ghaleb

Ahmed²,

Mosharafa

2023

Preprint

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We investigate a one-dimensional restriction of a nonlinear model of thermo-electroelasticity in extended thermodynamics and in the quasi-electrostatic regime (see [25]). An additional dependence of the thermal conductivity and the thermal relaxation time on temperature and heat flux is introduced. The aim of the present work is to assess the effect of some quadratic nonlinear couplings between the mechanical, thermal and electric fields. Such couplings are known to have a crucial effect on the stability of the solutions. It is confirmed that there are two speeds of wave propagation of disturbances, the coupled thermoelastic wave and the heat wave. Formulae are provided for both speeds, showing their explicit dependence on temperature, heat flux and electric field. The purely thermal case is briefly considered. The present results may be useful for the description of a broad range of interactions in polarizable materials and for the design of such materials.

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Section: Dimension Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

One-dimensional nonlinear model of generalized thermo-electroelasticity

Ghaleb

Ahmed²,

Mosharafa

2023

Preprint

View full text Add to dashboard Cite

show abstract

One-dimensional nonlinear model of generalized thermo-electroelasticity

2023

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We investigate a one-dimensional restriction of a nonlinear model of thermo-electroelasticity in extended thermodynamics and in the quasi-electrostatic regime (see Ghaleb et al. in Int J Eng Sci 119:29–39, 2017. https://doi.org/10.1016/j.ijengsci.2017.06.010). An additional dependence of the thermal conductivity and the thermal relaxation time on temperature and heat flux is introduced. The aim of the present work is to assess the effect of some quadratic nonlinear couplings between the mechanical, thermal and electric fields. Such couplings are known to have a crucial effect on the stability of the solutions. It is confirmed that there are two speeds of wave propagation of disturbances, the coupled thermoelastic wave and the heat wave. Formulae are provided for both speeds, showing their explicit dependence on temperature, heat flux and electric field. The purely thermal case is briefly considered. The present results may be useful for the description of a broad range of interactions in large polarizable slabs of electro-thermoelastic materials and for the design of such materials.

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Heat traveling waves in rigid thermal conductors with phase lag and stability analysis

et al. 2022

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Recently, a model equation that describes nonlinear heat waves in a rigid thermal conductor has been derived. The system of the governing equations for temperature and heat flux is nonlinear. The objective of the present work is to find a variety of traveling wave solutions of this system of equations in the whole space. This is achieved by implementing the unified method. The obtained solutions are evaluated numerically and represented graphically. The behavior of these solutions is investigated, where it is shown that the temperature and the heat flux attain steady states in space, but increase with time. The effects of the characteristic length, time, heat flux, and reference temperature are studied via some material data. It is shown that the solutions may have the form of solitary wave, soliton, or soliton with double kinks. It is observed that the heat flux in the material is negative, this reflects the fact that heat flux is in the opposite direction of the normal vector to the material surface on which it is evaluated. The steady state solution of the considered model equation is studied. It is found that the stability of the solutions depends significantly on the wave number.

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A One-dimensional Model of Thermo-electroelasticity in Extended Thermodynamics

Cited by 3 publications

References 15 publications

One-dimensional nonlinear model of generalized thermo-electroelasticity

One-dimensional nonlinear model of generalized thermo-electroelasticity

One-dimensional nonlinear model of generalized thermo-electroelasticity

Heat traveling waves in rigid thermal conductors with phase lag and stability analysis

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