Magnetic order in spin-1 and spin-3/2 interpolating square-triangle Heisenberg antiferromagnets

Abstract

Using the coupled cluster method we investigate spin-s J1-J2' Heisenberg antiferromagnets (HAFs) on an infinite, anisotropic, triangular lattice when the spin quantum number s=1 or s=3/2. With respect to a square-lattice geometry the model has antiferromagnetic (J1 > 0) bonds between nearest neighbours and competing (J2' > 0) bonds between next-nearest neighbours across only one of the diagonals of each square plaquette, the same one in each square. In a topologically equivalent triangular-lattice geometry, we have two types of nearest-neighbour bonds: namely the J2' J1 bonds along parallel chains and the J1 bonds producing an interchain coupling. The model thus interpolates between an isotropic HAF on the square lattice at = 0 and a set of decoupled chains at → ∞, with the isotropic HAF on the triangular lattice in between at = 1. For both the s=1 and the s=3/2 models we find a second-order quantum phase transition at c=0.615 0.010 and c=0.575 0.005 respectively, between a N\'eel antiferromagnetic state and a helical state. In both cases the ground-state energy E and its first derivative dE/d are continuous at =c, while the order parameter for the transition (viz., the average on-site magnetization) does not go to zero on either side of the transition. The transition at = c for both the s=1 and s=3/2 cases is analogous to that observed in our previous work for the s=1/2 case at a value c=0.80 0.01. However, for the higher spin values the transition is of continuous (second-order) type, as in the classical case, whereas for the s=1/2 case it appears to be weakly first-order in nature (although a second-order transition could not be excluded).