Consider the operator on $\ell^2(\mathbb{Z})$ $$ H = \Delta + v. $$ Here $\Delta$ is the nearest neighbour Laplacian on $\mathbb{Z}$, $\Delta_{k, \ell} =1 $ if $|k - \ell| =1 $ and zero otherwise, while $v_\ell , \ell \in \mathbb{Z}$ are independent identically distributed random variables with common distribution $\mu$.
If supp$\mu$ is bounded than we have the phenomenon of Anderson localization; with probability one, the spectrum of $H$ is pure point and the $\ell^2$-eigenvectors are exponentially localized. Focusing on the localization of the eigenvectors, this means that if $\psi$ is an eigenvector of $H$ then there exists $A, B >0 $ such that $$ \psi(k) \leq A \exp\left(-B|k| \right) $$
I was wondering if there are explicit bounds on $B$? I've been looking for papers that discuss the ${rate}$ of decay of eigenvectors for RSO but I haven't been able to find anything.
The proof of localization that I've seen relies on the fact that for every fixed $E \in \mathbb{R}$ the Lyapunov exponent $\gamma(E)$ of the corresponding transfer matrix is non-zero almost surely. Is it true that the rate of decay of an eigenfunction with eigenvalue $E$ is bounded by $\gamma(E)$?
Thank you for any help or sources you can point me to.
