ON THE DYNAMICS OF PULSED AND CONTINUOUS WAVE LASER MOLECULE INTERACTIONS AND THE EFFECTS OF PERMANENT DIPOLES

The interaction is studied of a Gaussian pulsed or a continuous wave (CW) electric field with a molecule that has a nonzero difference d between the permanent dipoles of the ground and excited states involved in a transition. The unusual spectral effects associated with the transition with d not-equal 0, relative to the often studied case with d = 0, have been investigated previously in the two-level approximation and for continuous wave lasers. The observation of these effects, including markedly increased periods of excited state populations and negative Bloch-Siegart shifts, will often require the intense fields associated with pulsed rather than purely continuous wave electric fields. Transitions induced by continuous wave and pulsed laser-'permanent dipole molecule' interactions, for high field intensities and varying pulse durations, are investigated with model calculations carried out using exact Floquet and symmetry-adapted Riemann product integral methods. These calculations illustrate how the increased period of the excited state populations for dipolar molecules, and the associated molecule-field couplings, can be probed by sampling the time-dependent populations of the excited states using ultrashort to short pulses. The discussion illustrates the predictive and interpretive importance of the analytical expression for the molecule-EMF coupling provided by the rotating wave approximation (RWA) with d not-equal 0. The examples considered show, for example, temporal beating effects between the field and the RWA or Rabi frequencies and their dependence on d.