*Accepted Paper*

**Inserted:** 1 dec 2008

**Journal:** Journal of Functional Analysis

**Year:** 2008

**Abstract:**

We introduce a framework for the study of nonlinear homogenization problems in the setting of stationary continuous processes in compact spaces. The latter are functions $f\circ T:*R*^n\times{\mathcal Q}\to{\mathcal Q}$ with $f\circ T(x,\omega)=f(T(x)\omega)$ where ${\mathcal Q}$ is a compact (Hausdorff topological) space, $f\in C({\mathcal Q})$ and $T(x):{\mathcal Q}\to{\mathcal Q}$, $x\in *R*^n$, is an $n$-dimensional continuous dynamical system endowed with an invariant Radon probability measure $\mu$. It can be easily shown that for almost all $\omega\in{\mathcal Q}$ the realization $f(T(x)\omega)$ belongs to an algebra with mean value, that is, an algebra of functions in $BUC(*R*^n)$ containing all translates of its elements and such that each of its elements possesses a mean value. This notion was introduced by Zhikov and Krivenko (1983). We then establish the existence of multiscale Young measures in the setting of algebras with mean value, where the compactifications of $*R*^n$ provided by such algebras plays an important role. These parametrized measures are useful in connection with the existence of correctors in homogenization problems. We apply this framework to the homogenization of a porous medium type equation in $*R*^n$ with a stationary continuous process as a stiff oscillatory external source.

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