English

Efficient three-body calculations with a two-body mapped grid method

Quantum Gases 2021-03-17 v1

Abstract

We investigate the prospects of combining a standard momentum space approach for ultracold three-body scattering with efficient coordinate space schemes to solve the underlying two-body problem. In many of those schemes the two-body problem is numerically restricted up to a finite interparticle distance rbr_\mathrm{b}. We analyze effects of this two-body restriction on the two- and three-body level using pairwise square-well potentials that allow for analytic two-body solutions and more realistic Lennard-Jones van der Waals potentials to model atomic interactions. We find that the two-body tt-operator converges exponentially in rbr_\mathrm{b} for the square-well interaction. Setting rbr_\mathrm{b} to 2000 times the range of the interaction, the three-body recombination rate can be determined accurately up to a few percent when the magnitude of the scattering length is small compared to rbr_\mathrm{b}, while the position of the lowest Efimov features is accurate up to the percent level. In addition we find that with the introduction of a momentum cut-off, it is possible to determine the three-body parameter in good approximation even for deep van der Waals potentials.

Keywords

Cite

@article{arxiv.2011.01707,
  title  = {Efficient three-body calculations with a two-body mapped grid method},
  author = {T. Secker and J. -L. Li and P. M. A. Mestrom and S. J. J. M. F. Kokkelmans},
  journal= {arXiv preprint arXiv:2011.01707},
  year   = {2021}
}
R2 v1 2026-06-23T19:53:07.909Z