Vanishing Wilson ratio as the hallmark of quantum spin-liquid models

Abstract

We present numerical results for finite-temperature T>0 thermodynamic quantities, entropy s(T), uniform susceptibility 0(T) and the Wilson ratio R(T), for several isotropic S=1/2 extended Heisenberg models which are prototype models for planar quantum spin liquids. We consider in this context the frustrated J1-J2 model on kagome, triangular, and square lattice, as well as the Heisenberg model on triangular lattice with the ring exchange. Our analysis reveals that typically in the spin-liquid parameter regimes the low-temperature s(T) remains considerable, while 0(T) is reduced consistent mostly with a triplet gap. This leads to vanishing R(T 0), being the indication of macroscopic number of singlets lying below triplet excitations. This is in contrast to J1-J2 Heisenberg chain, where R(T 0) either remains finite in the gapless regime, or the singlet and triplet gap are equal in the dimerized regime.