No Arabic abstract
We consider Schr{o}dinger operators on $L^{2}({mathbb R}^{d})otimes L^{2}({mathbb R}^{ell})$ of the form $ H_{omega}~=~H_{perp}otimes I_{parallel} + I_{perp} otimes {H_parallel} + V_{omega}$, where $H_{perp}$ and $H_{parallel}$ are Schr{o}dinger operators on $L^{2}({mathbb R}^{d})$ and $L^{2}({mathbb R}^{ell})$ respectively, and $ V_omega(x,y)$ : = $sum_{xi in {mathbb Z}^{d}} lambda_xi(omega) v(x - xi, y)$, $x in {mathbb R}^d$, $y in {mathbb R}^ell$, is a random surface potential. We investigate the behavior of the integrated density of surface states of $H_{omega}$ near the bottom of the spectrum and near internal band edges. The main result of the current paper is that, under suitable assumptions, the behavior of the integrated density of surface states of $H_{omega}$ can be read off from the integrated density of states of a reduced Hamiltonian $H_{perp}+W_{omega}$ where $W_{omega}$ is a quantum mechanical average of $V_{omega}$ with respect to $y in {mathbb R}^ell$. We are particularly interested in cases when $H_{perp}$ is a magnetic Schr{o}dinger operator, but we also recover some of the results from [24] for non-magnetic $H_{perp}$.
We consider Schrodinger operators with a random potential which is the square of an alloy-type potential. We investigate their integrated density of states and prove Lifshits tails. Our interest in this type of models is triggered by an investigation of randomly twisted waveguides.
We consider the Dirichlet Laplacian $H_gamma$ on a 3D twisted waveguide with random Anderson-type twisting $gamma$. We introduce the integrated density of states $N_gamma$ for the operator $H_gamma$, and investigate the Lifshits tails of $N_gamma$, i.e. the asymptotic behavior of $N_gamma(E)$ as $E downarrow inf {rm supp}, dN_gamma$. In particular, we study the dependence of the Lifshits exponent on the decay rate of the single-site twisting at infinity.
We study large time behavior of quantum walks (QW) with self-dependent coin. In particular, we show scattering and derive the reproducing formula for inverse scattering in the weak nonlinear regime. The proof is based on space-time estimate of (linear) QW such as Strichartz estimate. Such argument is standard in the study of nonlinear Schrodinger equations but it seems to be the first time to be applied to QW. We also numerically study the dynamics of QW and observe soliton like solutions.
We study large time behavior of quantum walks (QWs) with self-dependent (nonlinear) coin. In particular, we show scattering and derive the reproducing formula for inverse scattering in the weak nonlinear regime. The proof is based on space-time estimate of (linear) QWs such as dispersive estimates and Strichartz estimate. Such argument is standard in the study of nonlinear Schrodinger equations and discrete nonlinear Schrodinger equations but it seems to be the first time to be applied to QW.
We consider quantum walks with position dependent coin on 1D lattice $mathbb{Z}$. The dispersive estimate $|U^tP_c u_0|_{l^infty}lesssim (1+|t|)^{-1/3} |u_0|_{l^1}$ is shown under $l^{1,1}$ perturbation for the generic case and $l^{1,2}$ perturbation for the exceptional case, where $U$ is the evolution operator of a quantum walk and $P_c$ is the projection to the continuous spectrum. This is an analogous result for Schrodinger operators and discrete Schrodinger operators. The proof is based on the estimate of oscillatory integrals expressed by Jost solutions.