Time-resolved double-resonance spectroscopy: Lifetime measurement of the 6\,1g+(7,31) electronic state of molecular sodium

Abstract

We report on the lifetime measurement of the 6\,1g+ (7,31) state of Na2 molecules, produced in a heat-pipe oven, using a time-resolved spectroscopic technique. The 6\,1g+ (7,31) level was populated by two-step two-color double resonance excitation via the intermediate A\,1u+ (8,30) state. The excitation scheme was done using two synchronized pulsed dye lasers pumped by a Nd:YAG laser operating at the second harmonics. The fluorescence emitted upon decay to the final state was measured using a time-correlated photon counting technique, as a function of argon pressure. From this the radiative lifetime was extracted by extrapolating the plot to collision-free zero pressure. We also report calculated radiative lifetimes of the Na2 6\,1g+ ro-vibrational levels in the range of v=0-200 with J=1 and J=31 using the LEVEL program for bound-bound and the BCONT program for bound-free transitions. Our calculations reveal the importance of the bound-free transitions on the lifetime calculations and a large difference of about a factor of three between the J=1 and J=31 for the v=40 and v=100, due to the wavefunction alternating between having predominantly inner and outer well amplitude.