Theoretical investigation of the Freeman resonance in the dissociative ionization of H2+

Abstract

The dissociative ionization of H2+ in linearly polarized, 400 nm laser pulses is simulated by solving a three-particle time-dependent Schr\"odinger equation in full dimensionality. The joint energy spectra (JES) are computed for 8 and flat-top envelopes using the time-dependent surface flux (tSurff) methods. In JES, the energy sharing n photon energies ω of nuclear kinetic energy release (KER) EN and electronic KER Ee are well represented by EN+Ee=nω-Up+E0 for 8 pulses, but satisfy EN+Ee=nω+E0 for flat-top envelope, exposing a deviation of the ponderomotive energy Up, which has been observed in experiments, where E0 is the ground energy of H2+. The analysis of the wavefunction for electrons and protons after the pulse are presented, where we find Up is absorbed by the Freeman resonances between two excited ungerade states.