Moir\'e patterns in doubly differential electron momentum distributions in atomic ionization by midinfrared lasers

Abstract

We analyze the doubly differential electron momentum distribution in above-threshold ionization of atomic hydrogen by a linearly-polarized mid-infrared laser pulse. We reproduce side rings in the momentum distribution with forward-backward symmetry previously observed by Lemell et al. in Phys. Rev. A 87, 013421(2013), whose origin, as far as we know, has not been explained so far. By developing a Fourier theory of moir\'e patterns, we demonstrate that such structures stems from the interplay between intra- and intercycle interference patterns which work as two separate grids in the two-dimensional momentum domain. We use a three dimensional (3D) description based on the saddle-point approximation (SPA) to unravel the nature of these structures. When the periods of the two grids (intra- and intercycle) are similar, principal moir\'e patterns arise as concentric rings symmetrically in the forward and backward directions at high electron kinetic energy. Higher order moir\'e patterns are observed and characterized when the period of one grid is multiple of the other. We find a scale law for the position (in momentum space) of the center of the moir\'e rings in the tunneling regime. We verify the SPA predictions by comparison with time-dependent distorted wave strong-field approximation (SFA) calculations and the solutions of the full 3D time-dependent Schr\"odinger equation (TDSE).