Oriented Triplet p-Wave Pairing from Fermi surface Anisotropy and Nonlocal Attraction

Abstract

Using constrained-path quantum Monte Carlo, we map the ground-state phase diagram versus the nearest-neighbor (NN) attraction V and spin-dependent hopping anisotropy α for the two-dimensional attractive t--U--V Hubbard model at filling n0.85. We identify an onsite s-wave superfluid, a Cooper pair Bose metal with an uncondensed Bose surface, and an oriented equal-spin triplet p-wave pairing phase. The NN attraction activates the odd-parity channel, while hopping anisotropy suppresses the competing s-wave coherence and selects a px/py polar axis, and thus lowers the critical |Vc| for the onset of triplet-dominant p-wave pairing. A channel-resolved Landau analysis provides a criterion for the Landau p-wave scale Vc L(α), consistent with the observed anisotropy dependence of |Vc|. Our results establish how NN interaction and Fermi surface anisotropy cooperate to generate the oriented triplet p-wave pairing, and suggest that cold-atom and altermagnetic platforms could potentially realize this mechanism.