This paper is devoted to the homogenization of the heat conduction equation, with a homogeneous Dirichlet boundary condition, having a periodically oscillating thermal conductivity and a vanishing volumetric heat capacity. A homogenization result is established by using the evolution settings of multiscale and very weak multiscale convergence. In particular, we investigate how the relation between the volumetric heat capacity and the microscopic structure effects the homogenized problem and its associated local problem. It turns out that the properties of the microscopic geometry of the problem give rise to certain special effects in the homogenization result.
In this paper we establish compactness results of multiscale and very weak multiscale type for sequences bounded in L 2 (0, T ; H 1 0 (Ω)), fulfilling a certain condition. We apply the results in the homogenization of ε p ∂tuε (x, t) − ∇ • a x/ε, x/ε 2 , t/ε q , t/ε r ∇uε (x, t) = f (x, t), where 0 < p < q < r. The homogenization result reveals two special phenomena, namely that the homogenized problem is elliptic and that the matching for when the local problem is parabolic is shifted by p, compared to the standard matching that gives rise to local parabolic problems.
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