Quantum Diffusion and Eigenfunction Delocalization in a Random Band Matrix Model
arXiv:1002.1695 · doi:10.1007/s00220-011-1204-2
Abstract
We consider Hermitian and symmetric random band matrices $H$ in $d \geq 1$ dimensions. The matrix elements $H_{xy}$, indexed by $x,y \in Î\subset \Z^d$, are independent, uniformly distributed random variables if $\abs{x-y}$ is less than the band width $W$, and zero otherwise. We prove that the time evolution of a quantum particle subject to the Hamiltonian $H$ is diffusive on time scales $t\ll W^{d/3}$. We also show that the localization length of an arbitrarily large majority of the eigenvectors is larger than a factor $W^{d/6}$ times the band width. All results are uniform in the size $\absÎ$ of the matrix.
Minor corrections, Sections 4 and 11 updated