Analysis and approximation of a strain-limiting nonlinear elastic model

Journal article

Elastic solids with strain-limiting response to external loading represent an interesting class of material models, capable of describing stress concentration at strains with small magnitude. A theoretical justification of this class of models comes naturally from implicit constitutive theory. We investigate mathematical properties of static deformations for such strain-limiting nonlinear models. Focusing on the spatially periodic setting, we obtain results concerning existence, uniqueness and regularity of weak solutions, and existence of renormalized solutions for the full range of the positive scalar parameter featuring in the model. These solutions are constructed via a Fourier spectral method. We formulate a sufficient condition for ensuring that a renormalized solution is in fact a weak solution, and we comment on the extension of the analysis to nonperiodic boundary-value problems.

Authors: Bulíček, M; Málek, J; Süli, E

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: SAGE Publications
• Journal: Mathematics and Mechanics of Solids
• Volume: 20
• Issue: 1
• Pages: 92-118
• Publication date: 2014-08-18
• Acceptance date: 2014-02-27
• DOI: 10.1177/1081286514543601
• EISSN: 1741-3028
• ISSN: 1081-2865
• Language: English
• Keywords: uniqueness; linearized strain; weak solution; renormalized solutions; spatially periodic problem; regularity; stress concentration; strain-limiting model; first-order PDE system; existence of solution; elasticity; Fourier spectral method