A frustrated quantum spin- s model on the Union Jack lattice with spins s>1/2

Abstract

The zero-temperature phase diagrams of a two-dimensional frustrated quantum antiferromagnetic system, namely the Union Jack model, are studied using the coupled cluster method (CCM) for the two cases when the lattice spins have spin quantum number s=1 and s=3/2. The system is defined on a square lattice and the spins interact via isotropic Heisenberg interactions such that all nearest-neighbour (NN) exchange bonds are present with identical strength J1>0, and only half of the next-nearest-neighbour (NNN) exchange bonds are present with identical strength J2 J1 > 0. The bonds are arranged such that on the 2 × 2 unit cell they form the pattern of the Union Jack flag. Clearly, the NN bonds by themselves (viz., with J2=0) produce an antiferromagnetic N\'eel-ordered phase, but as the relative strength of the frustrating NNN bonds is increased a phase transition occurs in the classical case (s → ∞) at clc=0.5 to a canted ferrimagnetic phase. In the quantum cases considered here we also find strong evidence for a corresponding phase transition between a N\'eel-ordered phase and a quantum canted ferrimagnetic phase at a critical coupling c1=0.580 0.015 for s=1 and c1=0.545 0.015 for s=3/2. In both cases the ground-state energy E and its first derivative dE/d seem continuous, thus providing a typical scenario of a second-order phase transition at =c1, although the order parameter for the transition (viz., the average ground-state on-site magnetization) does not go to zero there on either side of the transition.