Collective Excitations, NMR, and Phase Transitions in Skyrme Crystals

TL;DR

This paper develops an effective low energy theory for Skyrme crystals in quantum Hall ferromagnets, explaining magnetic excitations, phase transitions, and predicting a significant increase in nuclear spin relaxation rates.

Contribution

It introduces a novel effective theory that accounts for low-energy magnetic excitations and phase transitions in Skyrme crystals, supported by Hartree-Fock calculations.

Findings

Magnetic excitations exist below the Larmor gap in Skyrme crystals.

Nuclear spin relaxation rate is predicted to be enhanced by a factor of 1000.

The theory predicts a rich set of quantum and classical phase transitions.

Abstract

At Landau level filling factors near nu =1, quantum Hall ferromagnets form a Skyrme crystal state with quasi-long-range translational and non-collinear magnetic order. We develop an effective low energy theory which explains the presence in these systems of magnetic excitations at low energies below the Larmor gap (Delta) and which predicts a dramatic enhancement of the nuclear spin relaxation rate by a factor of 1000. The effective theory predicts a rich set of quantum and classical phase transitions. Based in part on accurate time-dependent Hartree-Fock calculations of the ordered state collective excitation spectrum, we discuss aspects of the T-nu-Delta crystal phase diagram.