Abstract
The Fulde–Ferrell (FF) superfluid phase, in which fermions form finite momentum Cooper pairings, is well studied in spin-singlet superfluids in past decades. Different from previous works that engineer the FF state in spinful cold atoms, we show that the FF state can emerge in spinless Fermi gases confined in optical lattice associated with nearest-neighbor interactions. The mechanism of the spinless FF state relies on the split Fermi surfaces by tuning the chemistry potential, which naturally gives rise to finite momentum Cooper pairings. The phase transition is accompanied by changed Chern numbers, in which, different from the conventional picture, the band gap does not close. By beyond-mean-field calculations, we find the finite momentum pairing is more robust, yielding the system promising for maintaining the FF state at finite temperature. Finally we present the possible realization and detection scheme of the spinless FF state.
Highlights
Cold atoms in optical lattices provide an ideal experimental plateau for quantum simulation of the quantum many-body system
Different from previous works that focus on spinful systems, we show that FF superfluids can emerge in spinless ultracold Fermi gases trapped in a twodimensional (2D) optical lattice
We find that the FF state appears in the high filling regime when U exceeds a critical value in BCS–Bose-Einstein-condensation(BEC) crossover
Summary
Cold atoms in optical lattices provide an ideal experimental plateau for quantum simulation of the quantum many-body system. In searching FF superfluids in cold atoms, the earlier advances [18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28] bear similarities that they all focus on a spinful system. In these systems, the contact interaction between opposite pseudo-spin atoms plays the key role for the superfluid phases. Different from previous works that focus on spinful systems, we show that FF superfluids can emerge in spinless ultracold Fermi gases trapped in a twodimensional (2D) optical lattice.
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