Optical probes of two-component pairing states in transition metal dichalcogenides

Abstract

Signatures of unconventional superconductivity have been recently observed in certain transition metal dichalcogenides (TMDs), including 4Hb-TaS2 and monolayer 2H-NbSe2. While the pairing channel remains unknown, it has been argued that spin fluctuations can stabilize pairing in the two-component E' channel, a p-wave spin-triplet state which could be consistent with some of the reported signatures. Exploiting the particular multi-orbital character of the Fermi surface and the presence of Ising spin-orbit coupling, which enable finite optical conductivity in the clean limit, in this work we predict clear-cut optical signatures to detect and distinguish the chiral and nematic ground states of the E' pairing. We quantify how nematic E' states produce a diagonal anisotropy σxx\!≠\!σyy due to the broken threefold symmetry (C3), while chiral E' states yield a finite optical Hall conductivity σxyH due to broken time-reversal symmetry, and find both signals could be detected in current experiments. For instance, for realistic gaps in the meV range, we predict a relative anisotropy σ/σ10-5 in the nematic states, and a polar Kerr rotation of θK\!\!10-5 rad in the chiral states. These symmetry fingerprints provide a practical route to distinguish nematic and chiral superconducting order in TMD superconductors.