Luca Delfini, Stefano Lepri, Roberto Livi
Published 2005-05-11Version 1
The transport properties of the planar rotator model on a square lattice are analyzed by means of microcanonical and non--equilibrium simulations. Well below the Kosterlitz--Thouless--Berezinskii transition temperature, both approaches consistently indicate that the energy current autocorrelation displays a long--time tail decaying as t^{-1}. This yields a thermal conductivity coefficient which diverges logarithmically with the lattice size. Conversely, conductivity is found to be finite in the high--temperature disordered phase. Simulations close to the transition temperature are insted limited by slow convergence that is presumably due to the slow kinetics of vortex pairs.
Comments: Submitted to Journal of Statistical Mechanics: theory and experiment
Energy Transport in the Integrable System in Contact with Various Types of Phonon Reservoirs
Energy Transport in a One-Dimensional Granular Gas
Energy transport between two integrable spin chains
