C. Villagonzalo, R. A. Römer, M. Schreiber, A. MacKinnon
Published 2000-06-06Version 1
We study the thermal transport properties in three-dimensional disordered systems close to the metal-insulator transition within linear response. Using a suitable form for the energy-dependent conductivity $\sigma$, we show that the value of the dynamical scaling exponent for noninteracting disordered systems such as the Anderson model of localization can be reproduced. Furthermore, the values of the thermopower S have the right order of magnitude close to the transition as compared to the experimental results. A sign change in the thermoelectric power S - as is often observed in experiments - can also be modeled within the linear response formulation using modified experimental $\sigma$ data as input.
Comments: 9 pages, 10 figures, submitted to PRB
Journal: Phys. Rev. B, vol. 62 (2000), 16446-16452
Metal-insulator transition in Hubbard-like models with random hopping
Energy level statistics at the metal-insulator transition in the Anderson model of localization with anisotropic hopping
Metal-insulator transition in disordered systems from the one-body density matrix
