English

Wigner function for noninteracting fermions in hard wall potentials

Statistical Mechanics 2021-07-28 v2 Quantum Gases Mathematical Physics math.MP

Abstract

The Wigner function WN(x,p)W_N({\bf x}, {\bf p}) is a useful quantity to characterize the quantum fluctuations of an NN-body system in its phase space. Here we study WN(x,p)W_N({\bf x}, {\bf p}) for NN noninteracting spinless fermions in a dd-dimensional spherical hard box of radius RR at temperature T=0T=0. In the large NN limit, the local density approximation (LDA) predicts that WN(x,p)1/(2π)dW_N({\bf x}, {\bf p}) \approx 1/(2 \pi \hbar)^d inside a finite region of the (x,p)({\bf x}, {\bf p}) plane, namely for x<R|{\bf x}| < R and p<kF|{\bf p}| < k_F where kFk_F is the Fermi momentum, while WN(x,p)W_N({\bf x}, {\bf p}) vanishes outside this region, or "droplet", on a scale determined by quantum fluctuations. In this paper we investigate systematically, in this quantum region, the structure of the Wigner function along the edge of this droplet, called the Fermi surf. In one dimension, we find that there are three distinct edge regions along the Fermi surf and we compute exactly the associated nontrivial scaling functions in each regime. We also study the momentum distribution ρ^N(p)\hat \rho_N(p) and find a striking algebraic tail for very large momenta ρ^N(p)1/p4\hat \rho_N(p) \propto 1/p^4, well beyond kFk_F, reminiscent of a similar tail found in interacting quantum systems (discussed in the context of Tan's relation). We then generalize these results to higher dd and find, remarkably, that the scaling function close to the edge of the box is universal, i.e., independent of the dimension~dd.

Keywords

Cite

@article{arxiv.2104.05068,
  title  = {Wigner function for noninteracting fermions in hard wall potentials},
  author = {Benjamin De Bruyne and David S. Dean and Pierre Le Doussal and Satya N. Majumdar and Gregory Schehr},
  journal= {arXiv preprint arXiv:2104.05068},
  year   = {2021}
}

Comments

31 pages, 14 figures

R2 v1 2026-06-24T01:03:25.243Z