Spin-stiffness of anisotropic Heisenberg model on square lattice and possible mechanism for pinning of the electronic liquid crystal direction in YBCO

Abstract

Using series expansions and spin-wave theory we calculate the spin-stiffness anisotropy sx/sy in Heisenberg models on the square lattice with anisotropic couplings Jx,Jy. We find that for the weakly anisotropic spin-half model (Jx≈ Jy), sx/sy deviates substantially from the naive estimate sx/sy ≈ Jx/Jy. We argue that this deviation can be responsible for pinning the electronic liquid crystal direction, a novel effect recently discovered in YBCO. For completeness, we also study the spin-stiffness for arbitrary anisotropy Jx/Jy for spin-half and spin-one models. In the limit of Jy/Jx 0, when the model reduces to weakly coupled chains, the two show dramatically different behavior. In the spin-one model, the stiffness along the chains goes to zero, implying the onset of Haldane-gap phase, whereas for spin-half the stiffness along the chains increases monotonically from a value of 0.18 Jx for Jy/Jx=1 towards 0.25 Jx for Jy/Jx 0. Spin-wave theory is extremely accurate for spin-one but breaks down for spin-half presumably due to the onset of topological terms.