Cross-calibration of atomic pressure sensors and deviation from quantum diffractive collision universality for light particles

Abstract

The total room-temperature, velocity-averaged cross section for atom-atom and atom-molecule collisions is well approximated by a universal function depending only on the magnitude of the leading order dispersion coefficient, C6. This feature of the total cross section together with the universal function for the energy distribution transferred by glancing angle collisions (PQDU6) can be used to empirically determine the total collision cross section and realize a self-calibrating, vacuum pressure standard. This was previously validated for Rb+N2 and Rb+Rb collisions. However, the post-collision energy distribution is expected to deviate from PQDU6 in the limit of small C6 and small reduced mass. Here we observe this deviation experimentally by performing a direct cross-species loss rate comparison between Rb+H2 and Li+H2 and using the ab initio value of σtot \, v Li+H2. We find a velocity averaged total collision cross section ratio, R = σtot \, v Li+H2 : σtot \, v Rb+H2 = 0.83(5). Based on an ab initio computation of σtot \, v Li+H2 = 3.13(6)× 10-15 m3/s, we deduce σtot \, v Rb+H2 = 3.8(2) × 10-15 m3/s, in agreement with a Rb+H2 ab initio value of σtot v Rb+H2 = 3.57 × 10-15 m3/s.By contrast, fitting the Rb+H2 loss rate as a function of trap depth to the universal function we find σtot \, v Rb+H2 = 5.52(9) × 10-15 m3/s. Finally, this work demonstrates how to perform a cross-calibration of sensor atoms to extend and enhance the cold atom based pressure sensor.