We study the energy decay of the solutions of a linear homogeneous anisotropic thermoelastic diffusion system with second sound and dissipative linear boundary condition which well describes a material for which the domain outside the body consists in a material of viscoelastic type. The thermal and diffusion disturbances are modeled by Cattaneo-Maxwell law for heat and diffusion equations to remove the physical paradox of infinite propagation speed in the classical theory within Fourier’s law. The system of equations in this case is a coupling of three hyperbolic equations. By introducing a boundary free energy, we prove that, if the memory kernel exponentially decays in time then also the energy exponentially decays. Finally, we generalize the obtained results to the Gurtin-Pipkin model.
M. Aouadi, B. Lazzari, R. Nibbi (2013). Energy decay in thermoelastic diffusion theory with second sound and dissipative boundary. MECCANICA, 48(9), 2159-2171 [10.1007/s11012-013-9731-x].
Energy decay in thermoelastic diffusion theory with second sound and dissipative boundary
LAZZARI, BARBARA;NIBBI, ROBERTA
2013
Abstract
We study the energy decay of the solutions of a linear homogeneous anisotropic thermoelastic diffusion system with second sound and dissipative linear boundary condition which well describes a material for which the domain outside the body consists in a material of viscoelastic type. The thermal and diffusion disturbances are modeled by Cattaneo-Maxwell law for heat and diffusion equations to remove the physical paradox of infinite propagation speed in the classical theory within Fourier’s law. The system of equations in this case is a coupling of three hyperbolic equations. By introducing a boundary free energy, we prove that, if the memory kernel exponentially decays in time then also the energy exponentially decays. Finally, we generalize the obtained results to the Gurtin-Pipkin model.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
