Equilibrium Partition Function of Non-Relativistic CFTs in Harmonic Trap
Abstract
We investigate the equilibrium partition function of non-relativistic conformal field theories in harmonic quantization. We first analyze the hydrodynamic regime and show that, at leading order, the partition function exhibits a universal structure determined by the equation of state: the logarithm of the partition function develops simple poles in ω2-a2, where ω is the harmonic trapping frequency and a are angular velocities acting as chemical potentials for angular momentum. The corresponding residue is determined by a single-variable function of μ/T, with μ the particle-number chemical potential and T the temperature. We then study the large-angular-momentum limit aω. In this regime centrifugal effects nearly cancel the trapping potential, and the logarithm of the partition function again exhibits simple poles in ω2-a2, but with a less universal residue depending separately on μ/T and ω/T. As explicit examples we analyze superfluid systems realizable in cold-atom experiments, in particular fermions at unitarity confined in a harmonic trap.
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