Quantized Lattice Dynamic Effects on the Spin-Peierls Transition
Abstract
The density matrix renormalization group method is used to investigate the spin-Peierls transition for Heisenberg spins coupled to quantized phonons. We use a phonon spectrum that interpolates between a gapped, dispersionless (Einstein) limit to a gapless, dispersive (Debye) limit. A variety of theoretical probes are used to determine the quantum phase transition, including energy gap crossing, a finite size scaling analysis, bond order auto-correlation functions, and bipartite quantum entanglement. All these probes indicate that in the antiadiabatic phonon limit a quantum phase transition of the Berezinskii-Kosterlitz-Thouless type is observed at a non-zero spin-phonon coupling, . An extrapolation from the Einstein limit to the Debye limit is accompanied by an increase in for a fixed optical () phonon gap. We therefore conclude that the dimerized ground state is more unstable with respect to Debye phonons, with the introduction of phonon dispersion renormalizing the effective spin-lattice coupling for the Peierls-active mode. We also show that the staggered spin-spin and phonon displacement order parameters are unreliable means of determining the transition.
Cite
@article{arxiv.1007.3860,
title = {Quantized Lattice Dynamic Effects on the Spin-Peierls Transition},
author = {Christopher J. Pearson and William Barford and Robert J. Bursill},
journal= {arXiv preprint arXiv:1007.3860},
year = {2015}
}
Comments
To be published in Phys. Rev. B