S wave superconductivity in newly discovered superconductor BaTi2Sb2O revealed by 121/123Sb-NMR/Nuclear Quadrupole Resonance measurements

Abstract

We report the 121/123Sb-NMR/nuclear quadrupole resonance (NQR) measurements on the newly-discovered superconductor BaTi2Sb2O with a two-dimensional Ti2O square-net layer formed with Ti3+ (3d1). NQR measurements revealed that the in-plane four-fold symmetry is broken at the Sb site below T A 40 K, without an internal field appearing at the Sb site. These exclude a spin-density wave (SDW)/ charge density wave (CDW) ordering with incommensurate correlations, but can be understood with the commensurate CDW ordering at T A. The spin-lattice relaxation rate 1/T1, measured at the four-fold symmetry breaking site, decreases below superconducting (SC) transition temperature T c, indicative of the microscopic coexistence of superconductivity and the CDW/SDW phase below T A. Furthermore, 1/T1 of 121Sb-NQR shows a coherence peak just below T c and decreases exponentially at low temperatures. These results are in sharp contrast with those in cuprate and iron-based superconductors, and strongly suggest that its SC symmetry is classified to an ordinary s-wave state.