Quasiclassical magnetic order and its loss in a spin-1/2 Heisenberg antiferromagnet on a triangular lattice with competing bonds

Abstract

We use the coupled cluster method (CCM) to study the zero-temperature ground-state (GS) properties of a spin-1/2 J1--J2 Heisenberg antiferromagnet on a triangular lattice with competing nearest-neighbor and next-nearest-neighbor exchange couplings J1>0 and J2 J1>0, respectively, in the window 0 ≤ < 1. The classical version of the model has a single GS phase transition at cl=1/8 in this window from a phase with 3-sublattice antiferromagnetic (AFM) 120 N\'eel order for < cl to an infinitely degenerate family of 4-sublattice AFM N\'eel phases for > cl. This classical accidental degeneracy is lifted by quantum fluctuations, which favor a 2-sublattice AFM striped phase. For the quantum model we work directly in the thermodynamic limit of an infinite number of spins, with no consequent need for any finite-size scaling analysis of our results. We perform high-order CCM calculations within a well-controlled hierarchy of approximations, which we show how to extrapolate to the exact limit. In this way we find results for the case = 0 of the spin-1/2 model for the GS energy per spin, E/N=-0.5521(2)J1, and the GS magnetic order parameter, M=0.198(5), which are among the best available. For the spin-1/2 J1--J2 model we find that the classical transition at =cl is split into two quantum phase transition at c1=0.060(10) and c2=0.165(5). The two quasiclassical AFM states (viz., the 120 N\'eel state and the striped state) are found to be the stable GS phases in the regime < c1 and > c2, respectively, while in the intermediate regimes c1 < < c2 the stable GS phase has no evident long-range magnetic order.