Convergence Relative to a Microstructure : Properties, Optimal Bounds and Application

Abstract

In this work, we study a new notion involving convergence of microstructures represented by matrices Bε related to the classical H-convergence of Aε. It incorporates the interaction between the two microstructures. This work is about its effects on various aspects : existence, examples, optimal bounds on emerging macro quantities, application etc. Five among them are highlighted below : (1) The usual arguments based on translated inequality, H-measures, Compensated Compactness etc for obtaining optimal bounds are not enough. Additional compactness properties are needed. (2) Assuming two-phase microstructures, the bounds define naturally four optimal regions in the phase space of macro quantities. The classically known single region in the self-interacting case , namely Bε= Aε can be recovered from them, a result that indicates we are dealing with a true extension of the G-closure problem. (3) Optimality of the bounds is not immediate because of (a priori) non-commutativity of macro-matrices, an issue not present in the self-interacting case. Somewhat surprisingly though, commutativity follows a posteriori. (4) From the application to "Optimal Oscillation-Dissipation Problems", it emerges that oscillations and dissipation can co-exist optimally and the microstructures behind them need not be the same though they are closely linked. Furthermore, optimizers are found among N-rank laminates with interfaces. This is a new feature. (5) Explicit computations in the case of canonical microstructures are performed, in which we make use of H-measure in a novel way.