A. Mobius, P. Thomas, J. Talamantes, C. J. Adkins
Published 2001-11-01Version 1
The specific heat of the Coulomb glass is studied by numerical simulations. Both the lattice model with various strengths of disorder, and the random-position model are considered for the one- to three-dimensional cases. In order to extend the investigations down to very low temperatures where the many-valley structure of the configuration space is of great importance we use a hybrid-Metropolis procedure. This algorithm bridges the gap between Metropolis simulation and analytical statistical mechanics. The analysis of the simulation results shows that the correlation length of the relevant processes is rather small, and that multi-particle processes yield an essential contribution to the specific heat in all cases except the one-dimensional random-position model.
Comments: Contribution to the Festschrift dedicated to Prof. Michael Pollak on the occasion of his 75th birthday
Journal: Phil. Mag. B, 81, 1105 (2001)
The specific heat of the rwo-dimensional +/-J Ising model
The specific heat and optical birefringence of Fe(0.25)Zn(0.75)F2
Simulation of the phononless hopping in a Coulomb glass
