English

Properties of fermionic systems with the Path-integral ground state method

Quantum Gases 2023-05-10 v2 Other Condensed Matter

Abstract

We investigate strongly correlated many-body systems composed of bosons and fermions with a fully quantum treatment using the path-integral ground state method, PIGS. To account for the Fermi-Dirac statistics, we implement the fixed-node approximation into PIGS, which we then call FN-PIGS. In great detail, we discuss the pair density matrices we use to construct the full density operator in coordinate representation, a vital ingredient of the method. We consider the harmonic oscillator as a proof-of-concept and, as a platform representing quantum many-body systems, we explore helium atoms. Pure 4^4He systems demonstrate most of the features of the method. Complementarily, for pure 3^3He, the fixed-node approximation resolves the ubiquitous sign problem stemming from anti-symmetric wave functions. Finally, we investigate 3^3He-4^4He mixtures, demonstrating the method's robustness. One of the main features of FN-PIGS is its ability to estimate any property at temperature T=0T=0 without any additional bias apart from the FN approximation; biases from long simulations are also excluded. In particular, we calculate the correlation function of pairs of equal and opposite spins and precise values of the 3^3He kinetic energy in the mixture.

Keywords

Cite

@article{arxiv.2207.12294,
  title  = {Properties of fermionic systems with the Path-integral ground state method},
  author = {Sebastian Ujevick and V. Zampronio and B. R. de Abreu and S. A. Vitiello},
  journal= {arXiv preprint arXiv:2207.12294},
  year   = {2023}
}

Comments

40 pages, 11 figures

R2 v1 2026-06-25T01:12:37.560Z