Restricted basis set coupled-channel calculations on atom-molecule collisions in magnetic fields

Abstract

Rigorous coupled-channel quantum scattering calculations on molecular collisions in external fields are computationally demanding due to the need to account for a large number of coupled channels and multiple total angular momenta J of the collision complex. We show that by restricting the number of total angular momentum basis states to include only the states with helicities K Kmax it is possible to obtain accurate elastic and inelastic cross sections for He+CaH, Li+CaH and Li+SrOH collisions at a small fraction of the computational cost of the full coupled-channel calculations (where K is the projection of the molecular rotational angular momentum on the atom-diatom axis). The optimal size of the truncated helicity basis set depends on the mechanism of the inelastic process and on the magnitude of the external magnetic field. For dipolar-mediated spin relaxation in ultracold Li+CaH and Li+SrOH collisions, we find that a minimal helicity basis set (Kmax=0) gives quantitatively accurate results at ultralow collision energies, leading to nearly 90-fold gain in computational efficiency. Larger basis sets are required to accurately describe the resonance structure in Li+CaH and Li+SrOH inelastic cross sections in the few partial wave-regime (Kmax=3) as well as indirect spin relaxation in He+CaH collisions (Kmax=1). Our calculations indicate that the resonance structure is due to an interplay of the spin-rotation and Coriolis couplings between the basis states of different K and the couplings between the rotational states of the same K induced by the anisotropy of the interaction potential.