On the localization length of finite-volume random block Schr\"odinger operators
Abstract
We study a general class of random block Schr\"odinger operators (RBSOs) in dimensions 1 and 2, which naturally extend the Anderson model by replacing the random potential with a random block potential. Specifically, we focus on two RBSOs -- the block Anderson and Wegner orbital models -- defined on the d-dimensional torus ( Z/L Z)d. They take the form H=V + λ , where V is a block potential with i.i.d. Wd× Wd Gaussian diagonal blocks, describes interactions between neighboring blocks, and λ>0 is a coupling parameter. We normalize the blocks of so that each block has a Hilbert-Schmidt norm of the same order as the blocks of V. Assuming W Lδ for a small constant δ>0 and λ W-d/2, we establish the following results. In dimension d=2, we prove delocalization and quantum unique ergodicity for bulk eigenvectors. Combined with the localization result from arXiv:1608.02922, which holds under the condition λ W-d/2, this provides a rigorous proof of the Anderson localization-delocalization transition as λ crosses the critical threshold W-d/2. In dimension d=1, we show that the localization length of bulk eigenvectors is at least of order (Wλ)2, which is believed to be the correct scaling.
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