Loop-Cluster Simulation of the t-J Model on the Honeycomb Lattice

Abstract

Inspired by the lattice structure of the unhydrated variant of the superconducting material NaxCoO2 ·yH2O at x = 1/3, we study the t-J model on a honeycomb lattice by using an efficient loop-cluster algorithm. The low-energy physics of the undoped system and of the single hole sector is described by a systematic low-energy effective field theory. The staggered magnetization per spin Ms = 0.2688(3), the spin stiffness s = 0.102(2) J, the spin wave velocity c= 1.297(16) J a, and the kinetic mass M' of a hole are obtained by fitting the numerical Monte Carlo data to the effective theory predictions.