Unconventional Superfluidity in a model of Fermi-Bose Mixtures

TL;DR

This paper investigates a finite-temperature phase diagram of a Fermi-Bose mixture model on a 2D lattice, revealing unconventional superfluid phases, discontinuous transitions, and a close match of critical temperature ratios with real superconductor systems.

Contribution

It introduces a mean-field analysis of a Fermi-Bose mixture model showing unconventional superfluidity and complex phase transitions, aligning theoretical $T_c$ ratios with experimental high-temperature superconductors.

Findings

Identification of a dome-shaped superfluid phase in the phase diagram.

Discovery of first-order and zeroth-order phase transitions depending on fermion filling.

Close quantitative agreement of $T_c$/$T_F$ ratio with experimental high-$T_c$ superconductor data.

Abstract

A finite-temperature ($T>0$) study of a model of a mixture of spin-zero hardcore bosons and spinless fermions, with filling fractions $\rho_B$ and $\rho_F$, respectively, on a two-dimensional square lattice with composite hopping $t$ is presented. The composite hopping swaps the locations of a fermion and a boson that occupy nearest-neighbor sites of the lattice. The superfluid order parameter $\psi$, the femion hopping amplitude $\phi$, the chemical potential $\mu$, the free energy minimum $\tilde{F}$ and entropy $S$ are calculated in the limit $\rho_B+\rho_F=1$ within a mean-field approximation, and lead to a phase diagram in the $\rho_F - T$ plane. This phase diagram consists of a metallic superfluid phase under a dome-shaped $T(\rho_F)$, and insulating normal liquid and insulating normal gas phases outside the dome. These phases are separated by coupled discontinuous transitions as indicated by jumps in $\psi$ and $\phi$. The maximum critical transition temperature $T_c$ is observed very close to $\rho_F = 1/2$. While $\tilde{F} (T)$ is continuous with a derivative discontinuity at $T=T_c (\rho_F)$ for $0 <\rho_F \le 1/2$ (first-order transition), it becomes {\em discontinuous} for $\rho_F>1/2$ (zeroth-order transition), where the entropy becomes negative for a range of temperatures below $T_c$. The ratio of $T_c$ to Fermi band width agrees remarkably with the ratio of $T_c$/$T_F$ (where $T_F$ is the Fermi temperature) of unconventional superfluids and superconductors like Fermi-Bose mixtures, the high-$T_c$ cuprates, iron-based and hydride superconductors, that exhibit experimental values of $T_c$ spread over nine orders of magnitude from $\sim 200$nK to $\sim 260$K.