A. Perez-Garrido, M. Ortuno, A. Diaz-Sanchez, E. Cuevas
Published 1999-01-27Version 1
We perform a numerical simulation of energy relaxation in three-dimensional electron glasses in the strongly localized regime at finite temperatures. We consider systems with no interactions, with long-range Coulomb interactions and with short-range interactions, obtaining a power law relaxation with an exponent of 0.15, which is independent of the parameters of the problem and of the type of interaction. At very long times, we always find an exponential regime whose characteristic time strongly depends on temperature, system size, interaction type and localization radius. We extrapolate the longest relaxation time to macroscopic sizes and, for interacting samples, obtain values much larger than the measuring time. We finally study the number of electrons participating in the relaxation processes of very low energy configurations.
Comments: 6 eps figures. To be published in Phys. Rev. B
Journal: Phys. Rev. B, Vol 59, 5328 (1999)
Numerical Study of the Localization-Delocalization Transition for Vibrations in Amorphous Silicon
Numerical Study of a Many-Body Localized System Coupled to a Bath
Numerical study of the ordering of the +-J XY spin-glass ladder
