Anisotropic magnetism and spin fluctuations in the triangular-lattice spin-liquid candidate NaYbSe2: a single-crystal 23Na and 77Se NMR study

Abstract

The ytterbium-based delafossite NaYbSe2 is discussed as a prototype for a spin-orbit entangled, effective spin-1/2 triangular spin lattice with emerging antiferromagnetic correlations and a quantum-spin-liquid (QSL) ground state. We report on a comprehensive study of the static and dynamic anisotropic magnetism in single-crystalline samples of NaYbSe2, using NMR spectroscopy as a local-probe technique. We performed 23Na and 77Se NMR measurements in magnetic fields up to 16 T, applied along the in-plane and out-of-plane crystallographic directions and at temperatures from 300 down to 0.3 K. We could determine the anisotropic hyperfine contributions from the angular dependence of the 23Na and 77Se NMR spectra. In the paramagnetic regime, we probed the temperature dependence of the 23Na and 77Se spectral shift and the hyperfine coupling constants for fields applied along the principal crystal axes. The spin-lattice relaxation-rate data indicate critical spin fluctuations and the absence of long-range magnetic order at low magnetic fields and temperatures down to 0.3 K, evidenced by a monotonic increase of 1/T1 and associated spectral broadening. This is a clear proof of the evolution of a critical QSL ground state with residual fluctuations down to lowest temperatures. At elevated fields, we observe the emergence of long-range order, as the temperature-dependent 1/T1 rate passes through a pronounced maximum at TN at given field, followed by a decrease at lower temperatures. Further, we find an inhomogeneous broadening of the 23Na spectra below TN, probing the histogram of the local-field distribution in the presence of the field-induced order.