Time-resolved resonant photoionization of He using a time-dependent Feshbach method with ultrashort laser pulses

Abstract

We study the photoionization and autoionization of Helium atom subject to ultrashort laser pulses by using a Feshbach formalism in the time domain. We solve the time-dependent Schr\"odinger equation in terms of a configuration interaction (CI) spectral method, in which the total wavefunction is expanded with configurations defined within bound-like (Q) and scattering-like (P) halfspaces. The method allowsone to provide accurate descriptions of both the atomic structure (energy positions and widths) and the photodynamics. We illustrate our approach by i) calculating the time-resolved one-photon ionization below the He+ (n=2) ionization threshold, from 11Se and 2 1Po initial states, then reaching the lowest autoionizing states of 1Se, 1Po and 1De final symmetries ii) studing the temporal formation of the Fano profile of 1Po resonances and iii) showing its performance in obtaining the perturbative long-time limit of one- and two-photon ionization cross sections using ultrashort laser pulses following a recently developed procedure in Phys. Rev. A, 77, 032716 (2008).