$Γ$-convergence for power-law functionals with variable exponents

Abstract: We study the $\Gamma$-convergence of the functionals $F_n(u):= || f(\cdot,u(\cdot),Du(\cdot))||{p_n(\cdot)}$ and $\mathcal{F}_n(u):= \int{\Omega} \frac{1}{p_n(x)} f^{p_n(x)}(x,u(x),Du(x))dx$ defined on $X\in {L^1(\Omega,\mathbb{R}^d), L^\infty(\Omega,\mathbb{R}^d), C(\Omega,\mathbb{R}^d)}$ (endowed with their usual norms) with effective domain the Sobolev space $W^{1,p_n(\cdot)}(\Omega, \mathbb{R}^d )$. Here $\Omega\subseteq \mathbb{R}^N$ is a bounded open set, $N,d \ge 1$ and the measurable functions $p_n: \overline{\Omega} \rightarrow (1, + \infty) $ satisfy the conditions ${\mathop{\rm ess: sup }}{\ \overline \Omega} p_n \le \, \beta \, {\mathop{\rm ess: inf }}{\ \overline \Omega} p_n $ for a fixed constant $\beta > 1$ and $ {\mathop{\rm ess: inf }}{\ \overline \Omega} p_n \rightarrow + \infty$ as $n \rightarrow + \infty$. We show that when $f(x,u,\cdot)$ is level convex and lower semicontinuous and it satisfies a uniform growth condition from below, then, as $n\to \infty$, the sequences $(F_n)_n$ $\Gamma$-converges in $X$ to the functional $F$ represented as $F(u)= || f(\cdot,u(\cdot),Du(\cdot))||{\infty}$ on the effective domain $W^{1,\infty}(\Omega, \mathbb{R}^d )$. Moreover we show that the $\Gamma$-$\lim_n \mathcal F_n$ is given by the functional $ \mathcal{F}(u):=\left{\begin {array}{lll} !!!!!! & 0 & \hbox{if } || f(\cdot,u(\cdot),Du(\cdot)) ||_{\infty}\leq 1,\ !!!!!! & +\infty & \hbox{otherwise in } X.\ \end{array}\right. $