A symmetry breaking phenomenon for anisotropic harmonic maps from a 2D annulus into S1
Abstract
In a two dimensional annulus A=\x∈ R2: <|x|<1\, ∈ (0,1), we characterize 0-homogeneous minimizers, in H1(A; S1) with respect to their own boundary conditions, of the anisotropic energy equation* Eδ(u)=∫A |∇ u|2 +δ ( (∇· u)2-(∇× u)2) \, dx, δ∈ (-1,1). equation* Even for a small anisotropy 0<|δ| 1, we exhibit qualitative properties very different from the isotropic case δ=0. In particular, 0-homogeneous critical points of degree d 0,1,2 are always local minimizers, but in thick annuli ( 1) they are not minimizers: the 0-homogeneous symmetry is broken. One corollary is that entire solutions to the anisotropic Ginzburg-Landau system have a far-field behavior very different from the isotropic case studied by Brezis, Merle and Rivi\`ere. The tools we use include: ODE and variational arguments; asymptotic expansions, interpolation inequalities and explicit computations involving near-optimizers of these inequalities for proving that 0-homogeneous critical points are not minimizers in thick annuli.
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