Higher angular momentum pairing states in Sr2RuO4 in the presence of longer-range interactions
Abstract
The superconducting symmetry of Sr2RuO4 remains a puzzle. Time-reversal symmetry breaking dx2-y2 + igxy(x2-y2) pairing has been proposed for reconciling multiple key experiments. However, its stability remains unclear. In this work, we theoretically study the superconducting instabilities in Sr2RuO4, including the effects of spin-orbit coupling (SOC), in the presence of both local and longer-range interactions within a random phase approximation. We show that the inclusion of second nearest neighbor repulsions, together with non-local SOC in the B2g channel or orbital-anisotropy of the non-local interactions, can have a significant impact on the stability of both dx2-y2- and g-wave pairing channels. We analyze the properties, such as Knight shift and spontaneous edge current, of the realized dx2-y2 + ig, s+idxy and mixed helical pairings in different parameter spaces and find that the dx2-y2 + ig solution is in better agreement with the experimental data.
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