Constraints on superconducting pairing in altermagnets

Abstract

Superconductivity in the recently discovered altermagnetic materials hosts large prospects for both fundamental physics and technological applications. In this work we show that a characteristic spin-sublattice locking in altermagnets puts severe constraints on possible superconducting pairing. In particular, we uncover that the most common form of superconductivity, uniform s-wave spin-singlet pairing is not possible to achieve in altermagnets. Considering an effective model for a dx2-y2-wave altermagnet on a square lattice, we instead find that the most likely forms of spin-singlet pairing have dx2-y2- or extended s-wave symmetry. We also find that the simplest form of equal-spin-triplet p-wave pairing is not allowed, but it can only exist as a mixed-spin-triplet p-wave state. We verify these constraints on pairing within an interaction-induced model of altermagnetism, where we also establish their validity for finite-momentum pairing. Additionally we discuss the possible pairing symmetries for odd-frequency superconducting pairing. Due to the generality of our results, they are applicable to both intrinsic superconductivity and proximity-induced superconductivity in altermagnet-superconductor hybrid junctions.