A unified approach to the thermodynamics and quantum scaling functions of one-dimensional strongly attractive $SU(w)$ Fermi Gases

TL;DR

This paper provides a unified theoretical framework for understanding the thermodynamics and quantum critical behavior of one-dimensional strongly attractive $SU(w)$ Fermi gases, revealing universal scaling laws and critical phenomena.

Contribution

It introduces a unified derivation of thermodynamic quantities and scaling functions for 1D $SU(w)$ Fermi gases, highlighting their quantum critical universality class.

Findings

Identification of the quantum critical universality class with exponents z=2, ν=1/2

Determination of the quantum critical cone via specific heat peaks

Characterization of phase transitions through thermodynamic scaling functions

Abstract

In this letter we present a unified derivation of the pressure equation of states, thermodynamics and scaling functions for the one-dimensional (1D) strongly attractive Fermi gases with $SU(w)$ symmetry. These physical quantities provide a rigorous understanding on a universality class of quantum criticality characterised by the critical exponents $z=2$ and correlation length exponent $\nu=1/2$. Such a universality class of quantum criticality can occur when the Fermi sea of one branch of charge bound states starts to fill or become gapped at zero temperature. The quantum critical cone can be determined through the double peaks in specific heat which serve to mark two crossover temperatures fanning out from the critical point. Our method opens to further study on quantum phases and phase transitions in strongly interacting fermions with large $SU(w)$ and non-$SU(w)$ symmetries in one dimension.