Theoretical investigation on spin-forbidden cooling transitions of gallium hydride

Herein, the spin-forbidden cooling of a gallium hydride molecule is investigated using ab initio quantum chemistry. The cooling transition and the corresponding potential energy curves including , a3Π0−, a3Π0+, a3Π1, a3Π2, A1Π1, , 13Σ+1, , , and 23Σ+1 states are simulated based on the multi-reference configuration interaction approach plus Davidson corrections method. By solving the nuclear Schrodinger equation, we calculate the spectroscopic constants of these states, which are in good agreement with the available experimental values. Based on the transition data, there seems to be a theoretical puzzle: highly diagonally distributed Franck–Condon factor f00 for transitions , , and for the gallium hydride molecule but the intervening state A1Π1 for transition is prohibitive to laser cooling. In addition, the transition does not have a suitable rate of optical cycling owing to a large radiative lifetime for state. Our theoretical simulation indicates the solution to the puzzle: the transition has a high emission rate, and there is a suitable radiative lifetime for a3Π1 state, which can ensure rapid and efficient laser cooling of gallium hydride. The proposed laser drives transition by using three wavelengths (main pump laser λ00; two repumping lasers λ10 and λ21). These results demonstrate the possibility of laser-cooling the gallium hydride molecule, and a sub-microkelvin cool temperature can be reached for this molecule.