Low energy configurations of topological singularities in two dimensions: A $\Gamma$-convergence analysis of dipoles

TL;DR

This paper performs a detailed variational analysis of topological singularities in two-dimensional models, extending classical results to include low-energy dipole clusters that vanish in flat convergence.

Contribution

It introduces a $ ext{Gamma}$-convergence analysis that accounts for dipole clusters in low-energy regimes, refining classical vortex models.

Findings

Extended $ ext{Gamma}$-convergence results to dipole clusters

Characterized energy contributions of dipoles at small scales

Refined understanding of vortex and dipole configurations in low-energy limits

Abstract

This paper deals with the variational analysis of topological singularities in two dimensions. We consider two canonical zero-temperature models: the core radius approach and the Ginzburg-Landau energy. Denoting by $\varepsilon$ the length scale parameter in such models, we focus on the $|\log\varepsilon|$ energy regime. It is well known that, for configurations whose energy is bounded by $c|\log\varepsilon|$, the vorticity measures can be decoupled into the sum of a finite number of Dirac masses, each one of them carrying $\pi|\log\varepsilon|$ energy, plus a measure supported on small zero-average sets. Loosely speaking, on such sets the vorticity measure is close, with respect to the flat norm, to zero-average clusters of positive and negative masses. Here we perform a compactness and $\Gamma$-convergence analysis accounting also for the presence of such clusters of dipoles (on the range scale $\varepsilon^s$, for $0<s<1$), which vanish in the flat convergence and whose energy contribution has, so far, been neglected. Our results refine and contain as a particular case the classical $\Gamma$-convergence analysis for vortices, extending it also to low energy configurations consisting of just clusters of dipoles, and whose energy is of order $c|\log\varepsilon|$ with $c<\pi$\,.