Cascade of minimizers for a nonlocal isoperimetric problem in thin domains

For $\Omega_\e=(0,\e)\times (0,1)$ a thin rectangle, we consider minimization of the two-dimensional nonlocal isoperimetric problem given by \[ \inf_u E^{\gamma}_{\Omega_\e}(u)\] where \[ E^{\gamma}_{\Omega_\e}(u):= P_{\Omega_\e}(\{u(x)=1\})+\gamma\int_{\Omega_\e}\abs{\nabla{v}}^2\,dx \] and the minimization is taken over competitors $u\in BV(\Omega_\e;\{\pm 1\})$ satisfying a mass constraint $\fint_{\Omega_\e}u=m$ for some $m\in (-1,1)$. Here $P_{\Omega_\e}(\{u(x)=1\})$ denotes the perimeter of the set $\{u(x)=1\}$ in $\Omega_\e$, $\fint$ denotes the integral average and $v$ denotes the solution to the Poisson problem \[ -\Delta v=u-m\;\mbox{in}\;\Omega_\e,\quad\nabla v\cdot n_{\partial\Omega_\e}=0\;\mbox{on}\;\partial\Omega_\e,\quad\int_{\Omega_\e}v=0.\] We show that a striped pattern is the minimizer for $\e\ll 1$ with the number of stripes growing like $\gamma^{1/3}$ as $\gamma\to\infty.$ We then present generalizations of this result to higher dimensions.