Strong Convergence for Discrete Nonlinear Schr\"odinger equations in the Continuum Limit

Abstract

We consider discrete nonlinear Schr\"odinger equations (DNLS) on the lattice hZd whose linear part is determined by the discrete Laplacian which accounts only for nearest neighbor interactions, or by its fractional power. We show that in the continuum limit h 0, solutions to DNLS converge strongly in L2 to those to the corresponding continuum equations, but a precise rate of convergence is also calculated. In particular cases, this result improves weak convergence in Kirkpatrick, Lenzmann and Staffilani KLS. Our proof is based on a suitable adjustment of dispersive PDE techniques to a discrete setting. Notably, we employ uniform-in-h Strichartz estimates for discrete linear Schr\"odinger equations in HY, which quantitatively measure dispersive phenomena on the lattice. Our approach could be adapted to a more general setting like KLS as long as the desired Strichartz estimates are obtained.