NMR/NQR and AC-susceptibility Studies in the Weyl Semimetal Superconductor 1T-MoTe2 under Pressure

Abstract

We performed the Te-nuclear magnetic resonance, the Mo-nuclear quadrupole resonance, and the AC susceptibility in the Weyl semimetal superconductor 1T-MoTe2 at pressures up to 2.17~GPa. From the temperature and pressure dependence of the AC susceptibility, the superconducting transition temperature Tc and the upper critical field Hc2 were estimated. The results deviate from the Werthamer-Helfand-Hohenberg model but are well described by Hc2(T)=Hc2(0)[1-T/Tc]α. The latter fit yields Hc2(0)=1.50~T, Tc=3.81K, and α=1.1 at 2.17GPa, suggesting that the superconductivity lies in a strong-coupling regime. Since the nuclear spin-lattice relaxation rate divided by temperature, 1/T1T, follows the Korringa relation at ambient pressure, the increase in 1/T1T with pressure up to approximately 0.7~GPa indicates an increase in the density of states (DOS), N(E F). This trend mirrors the pressure dependence of Tc in the low-pressure region, consistent with the BCS mechanism. Above 0.7~GPa, however, N(E F) slightly decreases while Tc continues to rise, suggesting an additional pairing contribution beyond the conventional BCS picture. In the 1T phase at 2.17~GPa, the absence of a coherence peak in 1/T1T around T c, accompanied by a two-step decrease just below T c, was observed, which may be a signature of unconventional superconductivity.