Research article

Analytical and numerical analyses of a viscous strain gradient problem involving type Ⅱ thermoelasticity

  • Received: 26 March 2024 Revised: 26 April 2024 Accepted: 28 April 2024 Published: 15 May 2024
  • MSC : 35B40, 65M60, 74F05, 74H55, 74K10

  • In this paper, a thermoelastic problem involving a viscous strain gradient beam is considered from the analytical and numerical points of view. The so-called type Ⅱ thermal law is used to model the heat conduction and two possible dissipation mechanisms are introduced in the mechanical part, which is considered for the first time within strain gradient theory. An existence and uniqueness result is proved by using semigroup arguments, and the exponential energy decay is obtained. The lack of differentiability for the semigroup of contractions is also shown. Then, fully discrete approximations are introduced by using the finite element method and the backward time scheme, for which a discrete stability property and a priori error estimates are proved. The linear convergence is derived under suitable additional regularity conditions. Finally, some numerical simulations are presented to demonstrate the accuracy of the approximations and the behavior of the discrete energy decay.

    Citation: Noelia Bazarra, José R. Fernández, Jaime E. Muñoz-Rivera, Elena Ochoa, Ramón Quintanilla. Analytical and numerical analyses of a viscous strain gradient problem involving type Ⅱ thermoelasticity[J]. AIMS Mathematics, 2024, 9(7): 16998-17024. doi: 10.3934/math.2024825

    Related Papers:

  • In this paper, a thermoelastic problem involving a viscous strain gradient beam is considered from the analytical and numerical points of view. The so-called type Ⅱ thermal law is used to model the heat conduction and two possible dissipation mechanisms are introduced in the mechanical part, which is considered for the first time within strain gradient theory. An existence and uniqueness result is proved by using semigroup arguments, and the exponential energy decay is obtained. The lack of differentiability for the semigroup of contractions is also shown. Then, fully discrete approximations are introduced by using the finite element method and the backward time scheme, for which a discrete stability property and a priori error estimates are proved. The linear convergence is derived under suitable additional regularity conditions. Finally, some numerical simulations are presented to demonstrate the accuracy of the approximations and the behavior of the discrete energy decay.



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