Assignment of excited-state bond lengths using branching-ratio measurements: The B2+ state of BaH molecules

Abstract

Vibrational branching ratios in the B2+ -- X2+ and A2 -- X2+ optical-cycling transitions of BaH molecules are investigated using measurements and ab initio calculations. The experimental values are determined using fluorescence and absorption detection. The observed branching ratios have a very sensitive dependence on the difference in the equilibrium bond length between the excited and ground state, re: a 1 pm (.5\%) displacement can have a 25\% effect on the branching ratios but only a 1\% effect on the lifetime. The measurements are combined with theoretical calculations to reveal a preference for a particular set of published spectroscopic values for the B2+ state ( reB-X = +5.733 pm), while a larger bond-length difference ( reB-X = 6.3-6.7 pm) would match the branching-ratio data even better. By contrast, the observed branching ratio for the A23/2 -- X2+ transition is in excellent agreement with both the ab initio result and the spectroscopically measured bond lengths. This shows that care must be taken when estimating branching ratios for molecular laser cooling candidates, as small errors in bond-length measurements can have outsize effects on the suitability for laser cooling. Additionally, our calculations agree more closely with experimental values of the B2+ state lifetime and spin-rotation constant, and revise the predicted lifetime of the H2 state to 9.5 μs.