Sensitive detection of metastable NO and N2 by reactive collisions with laser-excited Li

Abstract

In a proof-of-principle experiment, we demonstrate that metastable nitric oxide molecules, NO(a4i), generated inside a pulsed, supersonic beam, can be detected by reactive gas-phase collisions with electronically excited Li atoms in the 22P3/2 state. Since the internal energy of NO(a4i, v ≤ 4) is lower than the ionization potential of Li in the 22S1/2 electronic ground state, we observe that the product ion yield arising from autoionizing NO(a4i)+Li(22S1/2) collisions is a factor of 21 lower than the ion yield from NO(a4i)+Li(22P3/2) collisions. We also compare our findings with measurements of relative rates for collisions of metastable N2+Li(22S1/2) and metastable N2+Li(22P3/2) reactive collisions. Using this detection method, we infer densities of ≈ 600 NO(a4i) molecules/cm3 and ≈ 6 · 104 metastable N2 molecules/cm3 in the interaction region. Our results also allow for an estimate of the fractional population of NO(a4i, v ≥ 5) prior to the collision process. The production of NO(a4i) in selected vibrational states using laser excitation from the X2r ground state will open possibilities for the detailed study of vibrational-state-selected NO(a4i)-Li(22P3/2) collisions.

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