Interacting Topological Defects on Frozen Topographies

TL;DR

This paper develops a theoretical framework for understanding disclination defects on curved surfaces, analyzing their interactions and configurations, especially on spheres, with implications for the Thomson problem.

Contribution

It introduces an effective free energy model for disclinations on arbitrary surfaces and explores defect configurations on spheres at different core energies.

Findings

Twelve disclinations form an icosahedron at high core energies.

Finite-length grain boundaries are favored at intermediate core energies.

The model applies to the Thomson problem of electrons on a sphere.

Abstract

We propose and analyze an effective free energy describing the physics of disclination defects in particle arrays constrained to move on an arbitrary two-dimensional surface. At finite temperature the physics of interacting disclinations is mapped to a Laplacian Sine-Gordon Hamiltonian suitable for numerical simulations. We then specialize to the case of a spherical crystal at zero temperature. The ground state is analyzed as a function of the ratio of the defect core energy to the Young's modulus. We argue that the core energy contribution becomes less and less important in the limit R >> a, where R is the radius of the sphere and a is the particle spacing. For large core energies there are twelve disclinations forming an icosahedron. For intermediate core energies unusual finite-length grain boundaries are preferred. The complicated regime of small core energies, appropriate to the limit R/a goes to infinity, is also addressed. Finally we discuss the application of our results to the classic Thomson problem of finding the ground state of electrons distributed on a two-sphere.