Homogenization and Phase Separation with Space Dependent Wells: The Subcritical Case

A variational model for the interaction between homogenization and phase separation is considered. The focus is on the regime where the latter happens at a smaller scale than the former, and when the wells of the double well potential are allowed to move and to have discontinuities. The zeroth and f...

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Bibliographic Details
Published in:Archive for rational mechanics and analysis 2023-10, Vol.247 (5), p.94, Article 94
Main Authors: Cristoferi, Riccardo, Fonseca, Irene, Ganedi, Likhit
Format: Article
Language:English
Subjects:
Classical Mechanics
Complex Systems
Composite materials
Digital Object Identifier
Discontinuity
Fluid- and Aerodynamics
Homogenization
Mathematical and Computational Physics
Mathematical models
Phase separation
Physics
Physics and Astronomy
Theoretical
Topology
Wells
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Summary:A variational model for the interaction between homogenization and phase separation is considered. The focus is on the regime where the latter happens at a smaller scale than the former, and when the wells of the double well potential are allowed to move and to have discontinuities. The zeroth and first order Γ -limits are identified. The topology considered for the latter is that of two-scale, since it encodes more information on the asymptotic local microstructure. In particular, when the wells are non-constant, the first order Γ -limit describes the contribution of microscopic phase separation, even in situations where there is no macroscopic phase separation. As a corollary, the minimum of the mass constrained minimization problem is characterized, and it is shown to depend on whether or not the wells are discontinuous. In the process of proving these results, the theory of inhomogeneous Modica Mortola functionals is strengthened.
ISSN:0003-9527
1432-0673
DOI:10.1007/s00205-023-01920-6