Universal relations and normal-state properties of a Fermi gas with laser-dressed mixed-partial-wave interactions

Abstract

In a recent experiment [P. Peng, et al., Phys. Rev. A 97, 012702 (2018)], it has been shown that the p-wave Feshbach resonance can be shifted toward the s-wave Feshbach resonance by a laser field. Based on this experiment, we study the universal relations and the normal-state properties in an ultracold Fermi gas with coexisting s- and p-wave interactions under optical control of a p-wave magnetic Feshbach resonance. Within the operator-product expansion, we derive the high-momentum tail of various observable quantities in terms of contacts. We find that the high-momentum tail becomes anisotropic. Adopting the quantum virial expansion, we calculate the normal-state contacts with and without a laser field for 40K atoms using typical experimental parameters. We show that the contacts are dependent on the laser dressing. We also reveal the interplay of laser dressing and different partial-wave interactions on various contacts. In particular, we demonstrate that the impact of the laser dressing in the p-wave channel can be probed by measuring the s-wave contacts, which is a direct manifestation of few-body effects on the many-body level. Our results can be readily checked experimentally.