Magnetic properties of nanoscale compass-Heisenberg planar clusters

TL;DR

This paper explores a spin-1/2 model on a square lattice combining quantum compass and Heisenberg interactions, revealing diverse phases, excitation gaps, and potential quantum computing applications with nanoscale clusters.

Contribution

It introduces a generalized compass-Heisenberg model, analyzes its phase diagram, and identifies robust low-energy excitations suitable for quantum information storage.

Findings

Ground state degeneracy is fragile and reduces to twofold with Heisenberg coupling.

Identifies various magnetic phases including ferromagnetic and antiferromagnetic.

Derives an effective 1D XYZ model explaining low-energy excitations.

Abstract

We study a model of spins 1/2 on a square lattice, generalizing the quantum compass model via the addition of perturbing Heisenberg interactions between nearest neighbors, and investigate its phase diagram and magnetic excitations. This model has motivations both from the field of strongly correlated systems with orbital degeneracy and from that of solid-state based devices proposed for quantum computing. We find that the high degeneracy of ground states of the compass model is fragile and changes into twofold degenerate ground states for any finite amplitude of Heisenberg coupling. By computing the spin structure factors of finite clusters with Lanczos diagonalization, we evidence a rich variety of phases characterized by Z2 symmetry, that are either ferromagnetic, C-type antiferromagnetic, or of Neel type, and analyze the effects of quantum fluctuations on phase boundaries. In the ordered phases the anisotropy of compass interactions leads to a finite excitation gap to spin waves. We show that for small nanoscale clusters with large anisotropy gap the lowest excitations are column-flip excitations that emerge due to Heisenberg perturbations from the manifold of degenerate ground states of the compass model. We derive an effective one-dimensional XYZ model which faithfully reproduces the exact structure of these excited states and elucidates their microscopic origin. The low energy column-flip or compass-type excitations are robust against decoherence processes and are therefore well designed for storing information in quantum computing. We also point out that the dipolar interactions between nitrogen-vacancy centers forming a rectangular lattice in a diamond matrix may permit a solid-state realization of the anisotropic compass-Heisenberg model.