6533b859fe1ef96bd12b76b4
RESEARCH PRODUCT
Finite-temperature geometric properties of the Kitaev honeycomb model
Bernardo SpagnoloBernardo SpagnoloAngelo CarolloLuca LeonforteFrancesco BasconeFrancesco BasconeDavide Valentisubject
Mathematics::Analysis of PDEsFOS: Physical sciencesPerturbation (astronomy)02 engineering and technologyCurvature01 natural sciencesSettore FIS/03 - Fisica Della Materiasymbols.namesakeMesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciencesFinite-temperature topological properties Kitaev honeycomb model Berry curvature mean Uhlmann curvature010306 general physicsPhase diagramMathematical physicsPhysicsSuperconductivityQuantum PhysicsCondensed Matter - Mesoscale and Nanoscale Physics021001 nanoscience & nanotechnologyMagnetic fieldsymbolsThermal stateBerry connection and curvatureQuantum Physics (quant-ph)0210 nano-technologyHamiltonian (quantum mechanics)description
We study finite temperature topological phase transitions of the Kitaev's spin honeycomb model in the vortex-free sector with the use of the recently introduced mean Uhlmann curvature. We employ an appropriate Fermionisation procedure to study the system as a two-band p-wave superconductor described by a BdG Hamiltonian. This allows to study relevant quantities such as Berry and mean Uhlmann curvatures in a simple setting. More specifically, we consider the spin honeycomb in the presence of an external magnetic field breaking time reversal symmetry. The introduction of such an external perturbation opens a gap in the phase of the system characterised by non-Abelian statistics, and makes the model to belong to a symmetry protected class, so that the Uhmann number can be analysed. We first consider the Berry curvature on a particular evolution line over the phase diagram. The mean Uhlmann curvature and the Uhlmann number are then analysed considering the system to be in a Gibbs state at finite temperature. Then, we show that the mean Uhlmann curvature describes a cross-over effect of the phases at high temperature. We also find an interesting nonmonotonic behaviour of the Uhlmann number as a function of the temperature in the trivial phase, which is due to the partial filling of the conduction band around Dirac points.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-10-09 | Physical Review B |