Collisional excitation transfer and quenching in Rb(5P)-methane mixtures

Abstract

We have examined fine-structure mixing between the rubidium 52P3/2 and 52P1/2 states along with quenching of these states due to collisions with methane gas. Measurements are carried out using ultrafast laser pulse excitation to populate one of the Rb 52P states, with the fluorescence produced through collisional excitation transfer observed using time-correlated single-photon counting. Fine-structure mixing rates and quenching rates are determined by the time dependence of this fluorescence. As Rb(52P) collisional excitation transfer is relatively fast in methane gas, measurements were performed at methane pressures of 2.5 - 25 Torr, resulting in a collisional transfer cross section (52P3/2 → 52P1/2) of (4.23 0.13) × 10-15 cm2. Quenching rates were found to be much slower and were performed over methane pressures of 50 - 4000 Torr, resulting in a quenching cross section of (7.52 0.10) × 10-19 cm2. These results represent a significant increase in precision compared to previous work, and also resolve a discrepancy in previous quenching measurements.