Charged particles on a 2D plane subject to anisotropic Jahn-Teller interactions

TL;DR

This paper investigates a 2D charged particle system with anisotropic Jahn-Teller interactions and Coulomb repulsion, revealing diverse mesoscopic textures and potential links to phenomena like superconductivity in oxides.

Contribution

It introduces a detailed analysis of how anisotropic Jahn-Teller interactions combined with Coulomb repulsion lead to complex self-organized structures in 2D charged systems.

Findings

First-order phase transition without Coulomb interaction.

Diverse mesoscopic textures depending on interaction ratio.

Charged objects with even particle numbers are more stable.

Abstract

The properties of a system of charged particles on a 2D lattice, subject to an anisotropic Jahn-Teller-type interaction and 3D Coulomb repulsion are investigated. In the mean-field approximation without Coulomb interaction, the system displays a phase transition of first order. When the long range Coulomb interaction is included, Monte Carlo simulations show that the system displays very diverse mesoscopic textures, ranging from spatially disordered pairs to ordered arrays of stripes, or charged clusters, depending only on the ratio of the two interactions (and the particle density). Remarkably, charged objects with even number of particles are more stable than with odd number of particles. We suggest that the diverse functional behaviour - including superconductivity - observed in oxides can be thought to arise from the self-organization of this type.