Alexander Elgart, Helge Krüger, Martin Tautenhahn, Ivan Veselić
Published 2011-07-14Version 1
We review recent results on localization for discrete alloy-type models based on the multiscale analysis and the fractional moment method, respectively. The discrete alloy-type model is a family of Schr\"odinger operators $H_\omega = - \Delta + V_\omega$ on $\ell^2 (\ZZ^d)$ where $\Delta$ is the discrete Laplacian and $V_\omega$ the multiplication by the function $V_\omega (x) = \sum_{k \in \ZZ^d} \omega_k u(x-k)$. Here $\omega_k$, $k \in \ZZ^d$, are i.i.d. random variables and $u \in \ell^1 (\ZZ^d ; \RR)$ is a so-called single-site potential. Since $u$ may change sign, certain properties of $H_\omega$ depend in a non-monotone way on the random parameters $\omega_k$. This requires new methods at certain stages of the localization proof.
Comments: Proceedings of the Spectral Days 2010, Pontificia Universidad Cat\'olica de Chile, Santiago
Wegner estimate for discrete Schrödinger operators with Gaussian random potentials
Fractional Moment Methods for Anderson Localization in the Continuum
Localization via fractional moments for models on $\mathbb{Z}$ with single-site potentials of finite support
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