Thermal Phase Structure of the Attractive Fermi Hubbard Model with Imaginary Chemical Potential

Abstract

We study the BCS--BEC crossover of the large N attractive Fermi-Hubbard model on a one-dimensional lattice using the mean field approximation in the presence of an imaginary chemical potential. We show that the crossover is governed by three parameters. The imaginary chemical potential iθ, the temperature via a thermal kernel g(β Ek,βθ) and the parameter δu whose sign controls the weak and strong coupling regimes. At the unitarity point (U=Uc), we find a thermal window φ=βθ=2π/3,4π/3 where the gap vanishes while the fermion number Nf, which quantifies the balance between particle-like and hole-like excitations, has a local maximum/minimum. Inside this thermal window BCS and BEC physics are await changes in the coupling to be selected as the dominant regime. We expect that our results will unveil a better understanding of pairing correlations in lattice many-body physics.