Abstract
The paper deals with the analysis of an influence of the thermal field and its relaxation properties on the compressional and flexural magnetoelastic waves propagation in a vibrating superconducting layer. The investigations have been confined only to the vortex elastic field in the type-II superconductor. The description is based on the extended thermodynamical model of interactions. Contrary to the existing dynamical descriptions of electromagnetothermoelastic interactions in solids and/or in the magnetic vortex field of elastic character in the type-II superconductor, the influence of the thermal field on the electromagnetoelastic field (or electromagnetoelastic waves in such a medium) has been considered by the use of the effective elastic coefficients dependent on temperature and the relaxation time of the thermal field in low temperatures.
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Communicated by Attila Imre.
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Maruszewski, B.T., Jankowska, M.A. & Starosta, R. Extended thermodynamics, effective elastic coefficients and electromagnetoelastic waves in superconducting layer. Continuum Mech. Thermodyn. 30, 1379–1386 (2018). https://doi.org/10.1007/s00161-017-0609-3
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DOI: https://doi.org/10.1007/s00161-017-0609-3