Magnetic properties of the spin-1 two-dimensional J1-J3 Heisenberg model on a triangular lattice

Abstract

Motivated by the recent experiment in NiGa2S4, the spin-1 Heisenberg model on a triangular lattice with the ferromagnetic nearest- and antiferromagnetic third-nearest-neighbor exchange interactions, J1 = -(1-p)J and J3 = pJ, J > 0, is studied in the range of the parameter 0 ≤ p ≤ 1. Mori's projection operator technique is used as a method, which retains the rotation symmetry of spin components and does not anticipate any magnetic ordering. For zero temperature several phase transitions are observed. At p ≈ 0.2 the ground state is transformed from the ferromagnetic order into a disordered state, which in its turn is changed to an antiferromagnetic long-range ordered state with the incommensurate ordering vector at p ≈ 0.31. With growing p the ordering vector moves along the line to the commensurate point Qc = (2 π /3, 0), which is reached at p = 1. The final state with the antiferromagnetic long-range order can be conceived as four interpenetrating sublattices with the 120 spin structure on each of them. Obtained results offer a satisfactory explanation for the experimental data in NiGa2S4.