Formation of stripes and slabs near the ferromagnetic transition

Abstract

We consider Ising models in d=2 and d=3 dimensions with nearest neighbor ferromagnetic and long-range antiferromagnetic interactions, the latter decaying as (distance)(-p), p>2d, at large distances. If the strength J of the ferromagnetic interaction is larger than a critical value Jc, then the ground state is homogeneous. It has been conjectured that when J is smaller than but close to Jc the ground state is periodic and striped, with stripes of constant width h=h(J), and h tends to infinity as J tends to Jc from below. (In d=3 stripes mean slabs, not columns.) Here we rigorously prove that, if we normalize the energy in such a way that the energy of the homogeneous state is zero, then the ratio e0(J)/eS(J) tends to 1 as J tends to Jc from below, with eS(J) being the energy per site of the optimal periodic striped/slabbed state and e0(J) the actual ground state energy per site of the system. Our proof comes with explicit bounds on the difference e0(J)-eS(J) at small but finite Jc-J, and also shows that in this parameter range the ground state is striped/slabbed in a certain sense: namely, if one looks at a randomly chosen window, of suitable size l (very large compared to the optimal stripe size h(J)), one finds a striped/slabbed state with high probability.