Half-vicinity model and a phase diagram for quantum oscillations in confined and degenerate Fermi gases

TL;DR

This paper introduces an analytical, material-independent model for quantum oscillations in confined Fermi gases, providing a phase diagram and accurate predictions for thermodynamic properties across different regimes.

Contribution

The authors develop a universal analytical model that separates quantum oscillations from classical behavior and constructs a phase diagram for confined Fermi gases, enhancing understanding of quantum regimes.

Findings

Accurately estimates quantum oscillations based on confinement and degeneracy.

Derives analytical expressions for phase transition interfaces in various dimensions.

Validates model accuracy through electronic specific heat capacity calculations.

Abstract

We propose an analytical model for the accurate calculation of size and density dependent quantum oscillations in thermodynamic and transport properties of confined and degenerate non-interacting Fermi gases. We provide a universal, material independent, recipe that explicitly separates oscillatory quantum regime from stationary classical regime. Our model quite accurately estimates quantum oscillations depending on confinement and degeneracy. We construct a phase diagram representing stationary and oscillatory regimes on degeneracy-confinement space. Analytical expressions of phase transition interfaces are derived for different dimensions. The critical point on the phase diagram, which separates entirely stationary and entirely oscillatory regions, is determined and their aspect ratio dependencies are examined. Quantum oscillations as well as their periods are analytically expressed for one-dimensional case. Accuracy of our model is verified through quantum oscillations in electronic specific heat capacity. We also compare the predictions of our half-vicinity model, based on bounded sums, with those of infinite sums, for the oscillatory violation of entropy-heat capacity equivalence in degenerate limit to show the accuracy of our model. Furthermore, similarities between functional behaviors of total occupancy variance and conventional density of states functions at Fermi level are discussed.