Spin Wave Theory of Spin 1/2 XY Model with Ring Exchange on a Triangular Lattice

Abstract

We present the linear spin wave theory calculation of the superfluid phase of a hard-core boson J-K model with nearest neighbour exchange J and four-particle ring-exchange K at half filling on the triangular lattice, as well as the phase diagrams of the system at zero and finite temperatures. We find that the pure J model (XY model) which has a well known uniform superfluid phase with an ordered parameter Mx=<Six>≠ 0 at zero temperature is quickly destroyed by the inclusion of a negative-K ring-exchange interactions, favouring a state with a (4π3, 0) ordering wavevector. We further study the behaviour of the finite-temperature Kosterlitz-Thouless phase transition (TKT) in the uniform superfluid phase, by forcing the universal quantum jump condition on the finite-temperature spin wave superfluid density. We find that for K 0, the phase boundary monotonically decreases to T=0 at K/J = -4/3, where a phase transition is expected and TKT decreases rapidly while for positive K, TKT reaches a maximum at some K≠ 0. It has been shown on a square lattice using quantum Monte Carlo(QMC) simulations that for small K 0 away from the XY point, the zero-temperature spin stiffness value of the XY model is decreasedF. Our result seems to agree with this trend found in QMC simulations.