English

Are smooth pseudopotentials a good choice for representing short-range interactions?

Quantum Gases 2019-03-27 v2

Abstract

When seeking a numerical representation of a quantum-mechanical multiparticle problem it is tempting to replace a singular short-range interaction by a smooth finite-range pseudopotential. Finite basis set expansions, e.g.~in Fock space, are then guaranteed to converge exponentially. The need to faithfully represent the artificial length scale of the pseudopotential, however, places a costly burden on the basis set. Here we discuss scaling relations for the required size of the basis set and demonstrate the basis set convergence on the example of a two-dimensional system of few fermions with short-range ss-wave interactions in a harmonic trapping potential. In particular we show that the number of harmonic-oscillator basis functions needed to reach a regime of exponential convergence for a Gaussian pseudopotential scales with the fourth power of the pseudopotential length scale, which can be improved to quadratic scaling when the basis functions are re-scaled appropriately. Numerical examples for three fermions with up to a few hundred single-particle basis functions are presented and implications for the feasibility of accurate numerical multi-particle simulations of interacting ultra-cold atom systems are discussed.

Keywords

Cite

@article{arxiv.1812.06521,
  title  = {Are smooth pseudopotentials a good choice for representing short-range interactions?},
  author = {Péter Jeszenszki and Ali Alavi and Joachim Brand},
  journal= {arXiv preprint arXiv:1812.06521},
  year   = {2019}
}

Comments

11 pages, 2 figures

R2 v1 2026-06-23T06:43:57.802Z