WIAS Preprint No. 2578, (2019)

Rate-independent evolution of sets



Authors

  • Rossi, Riccarda
    ORCID: 0000-0002-7808-0261
  • Stefanelli, Ulisse
  • Thomas, Marita
    ORCID: 0000-0001-9172-014X

2010 Mathematics Subject Classification

  • 35A15 35R37 49Q10 74R10

Keywords

  • Unidirectional evolution of sets by competition of perimeter and volume, minimizers of perimeter perturbed by a nonsmooth functional, minimizing movements, stability, energetic solutions

DOI

10.20347/WIAS.PREPRINT.2578

Abstract

The goal of this work is to analyze a model for the rate-independent evolution of sets with finite perimeter. The evolution of the admissible sets is driven by that of a given time-dependent set, which has to include the admissible sets and hence is to be understood as an external loading. The process is driven by the competition between perimeter minimization and minimization of volume changes. In the mathematical modeling of this process, we distinguish the adhesive case, in which the constraint that the (complement of) the `external load' contains the evolving sets is penalized by a term contributing to the driving energy functional, from the brittle case, enforcing this constraint. The existence of Energetic solutions for the adhesive system is proved by passing to the limit in the associated time-incremental minimization scheme. In the brittle case, this time-discretization procedure gives rise to evolving sets satisfying the stability condition, but it remains an open problem to additionally deduce energy-dissipation balance in the time-continuous limit. This can be obtained under some suitable quantification of data. The properties of the brittle evolution law are illustrated by numerical examples in two space dimensions.

Appeared in

  • Analysis of Evolutionary and Complex Systems: Issue on the Occasion of Alexander Mielke's 60th Birthday, M. Liero, S. Reichelt, G. Schneider, F. Theil, M. Thomas, eds., vol. 14 of Discrete and Continuous Dynamical Systems -- Series S, American Institute of Mathematical Sciences, Springfield, 2021, pp. 89--119, DOI 10.3934/dcdss.2020304 .

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