Observation of chiral solitons in the quantum spin liquid phase of LiCuVO4

Abstract

Quantum spin liquids represent a magnetic ground state arising in the presence of strong quantum fluctuations that preclude ordering down to zero temperature and leave clear fingerprints in the excitation spectra. While theory bears a variety of possible quantum spin liquid phases their experimental realization is still scarce. Here, we report the first experimental evidence of a vector-chiral quantum spin liquid state in the S=1/2 spin chain compound LiCuVO4 from measurements of the complex permittivity * in the GHz range. In zero magnetic field our results show short-lived thermally activated chiral fluctuations above the multiferroic phase transition at TN=2.4 K with divergent life-times when approaching TN. In * this fluctuation dynamics are seen as the slowing down of a relaxation with a critical dynamical exponent z ≈ 1.3 in agreement with mean-field predictions. When using a magnetic field to suppress TN towards 0 K the influence of quantum fluctuations is increased until they condense into the chrial spin liquid phase below 400 mK. Within this phase we measure a nearly-gapless chiral soliton excitation with a tiny energy gap of ESE≈14.1 μeV.