f-wave superfluidity from repulsive interaction in Rydberg-dressed Fermi gas

Abstract

Interacting Fermi gas provides an ideal model system to understand unconventional pairing and intertwined orders relevant to a large class of quantum materials. Rydberg-dressed Fermi gas is a recent experimental system where the sign, strength, and range of the interaction can be controlled. The interaction in momentum space has a negative minimum at qc inversely proportional to the characteristic length-scale in real space, the soft-core radius rc. We show theoretically that single-component (spinless) Rydberg-dressed Fermi gas in two dimensions has a rich phase diagram with novel superfluid and density wave orders due to the interplay of the Fermi momentum pF, interaction range rc, and interaction strength u0. For repulsive bare interactions u0>0, the dominant instability is f-wave superfluid for pFrc 2, and density wave for pFrc 4. The f-wave pairing in this repulsive Fermi gas is reminiscent of the conventional Kohn-Luttinger mechanism, but has a much higher Tc. For attractive bare interactions u0<0, the leading instability is p-wave pairing. The phase diagram is obtained from functional renormalization group that treats all competing many-body instabilities in the particle-particle and particle-hole channels on equal footing.