Rotational coherences in O2+ following strong-field ionization

Abstract

We investigate the wave packet that remains bound in the ground and excited cationic states of oxygen after strong-field ionization by an intense 800-nm pulse. Much weaker probe pulses (800 or 264 nm) are used to dissociate these still-bound cations. The momentum distribution of O+ is measured as a function of pump-probe delay and Fourier-transformed to obtain kinetic-energy-dependent and rotational-state-resolved quantum beat spectra. The sub-cm-1 resolution of the Fourier transform allows unambiguous identification of the electronic, vibrational, and rotational states populated by the pump and then dissociated by the probe. Although strong-field ionization is expected to populate the lower-lying X2g and a4u states more effectively than the b4-g state, a wave packet in the X2g state is seen only with the 264-nm probe and only weak signatures of the a4u states are found with either probe. The experiment confirms the role of the resonant coupling between the b4-g and a4u states by the 800 nm pulses [Xue et al., Phys. Rev. A 97, 043409 (2018)] and reveals the importance of rovibrational excitation in determining the momentum distribution of the O+ fragments. The strong X2g state contribution observed with the 264-nm probe also shows the importance of resonant coupling in the probe pulse. The sub-cm-1 resolution also resolves spin-orbit splitting in both the X2g and a4u state wave packets.