Simulating strongly correlated multiparticle systems in a truncated Hilbert space
Abstract
Representing a strongly interacting multi-particle wave function in a finite product basis leads to errors. Simple rescaling of the contact interaction can preserve the low-lying energy spectrum and long-wavelength structure of wave functions in one-dimensional systems and thus correct for the basis set truncation error. The analytic form of the rescaling is found for a two-particle system where the rescaling is exact. Detailed comparison between finite Hilbert space calculations and exact results for up to 5 particles show that rescaling can significantly improve the accuracy of numerical calculations in various external potentials. In addition to ground state energies, the low-lying excitation spectrum, density profile and correlation functions are studied. The results give a promising outlook for numerical simulations of trapped ultracold atoms.
Cite
@article{arxiv.1104.2627,
title = {Simulating strongly correlated multiparticle systems in a truncated Hilbert space},
author = {Thomas Ernst and David W. Hallwood and Jake Gulliksen and Hans-Dieter Meyer and Joachim Brand},
journal= {arXiv preprint arXiv:1104.2627},
year = {2011}
}
Comments
8 pages, 7 figures