Superconducting state of Sr2RuO4 in the presence of longer-range Coulomb interactions

Abstract

The symmetry of the superconducting condensate in Sr2RuO4 remains controversial after nuclear magnetic resonance (NMR) experiments recently overturned the dominant chiral p-wave paradigm. Several theoretical proposals have been put forward to account for existing experiments, including a d+ig-wave admixture, conjectured to be stabilized by longer-range Coulomb interactions. We perform a material-specific microscopic theoretical study of pairing by spin- and charge-fluctuations in Sr2RuO4, including the effects of spin-orbit coupling, and both local and longer-range Coulomb repulsion. The latter has important consequences for Sr2RuO4 due to the near-degeneracy of symmetry-distinct pairing states in this material. We find that both the g- and dx2-y2-wave channels remain noncompetitive compared to leading nodal s', dxy, and helical (p) solutions. This suggests nodal time-reversal symmetry broken s'+idxy or s'+ip phases, promoted by longer-range Coulomb repulsion, as the most favorable candidates for Sr2RuO4. We analyse the properties of these states, and show that the s'+idxy solution agrees with the bulk of available experimental data, including recent discoveries from NMR, muon spin relaxation (μSR), and ultrasound measurements.

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