Few-photon single ionization of cold rubidium in the over-the-barrier regime

Abstract

Photoionization of the rubidium (Rb) atoms cooled in a magneto-optical trap, characterized by the coexistence of the ground 5S1/2 and the excited 5P3/2 states, is investigated experimentally and theoretically with the 400 nm femtosecond laser pulses at intensities of I=3×109 W/cm2 - 4.5×1012 W/cm2. Recoil-ion momentum distribution (RIMD) of Rb+ exhibits rich ring-like structures and their energies correspond to one-photon ionization of the 5P3/2 state, two-photon and three-photon ionizations of the 5S1/2 state, respectively. With the increasing of I, we find that experimental signals near zero-momentum (NZM) in RIMDs resulted from the 5P3/2 state enhance dramatically and its peaked Rb+ momenta dwindle obviously while that from the 5S1/2 state is maintained. Meanwhile, the ion-yield ratio of the 5S1/2 over the 5P3/2 states varies from I to I1.5 as I increases. These features indicate a transition from perturbative ionization to strong-perturbative ionization for the 5P3/2 state. Numerical simulations by solving the time-dependent Schr\"odinger equation (TDSE) can qualitatively explain the measurements of RIMD, photoion angular distributions, as well as ion-yield ratio. However, some discrepancies still exist, especially for the NZM dip, which could stem from the electron-electron correlation that is neglected in the present TDSE simulations since we have adopted the single-active-electron approximation.