Thermal liquid-gas phase transition in a quasi-one-dimensional dipolar Fermi gas

We theoretically investigate thermodynamic properties in a quasi-one-dimensional single-component dipolar Fermi gas at finite temperatures. The self-bound fermionic droplet can be achieved by exchange correlations with the long-range dipole-dipole interactions under the quasi-one-dimensional confinement, where the interaction can be tuned by tilting the dipoles along the system coordinate. Using the Hartree-Fock approximation, we show how the liquid-gas phase transition occurs in this system, and elucidate the finite-temperature phase structure consisting of the gas phase, liquid phase, their coexistence, and the spinodal phase. We also discuss its similarity with the liquid-gas phase transition in nuclear matter through the comparison with phenomenological models. Our results would be useful for an interdisciplinary understanding of self-bound fermionic matter as well as an analog quantum simulation of nuclear systems.