Ground-state phases of the frustrated spin-1/2 J1--J2--J3 Heisenberg ferromagnet (J1<0) on the honeycomb lattice with J3=J2>0

Abstract

We study the ground-state (gs) properties of the frustrated spin-1/2 J1--J2--J3 Heisenberg model on a honeycomb lattice with ferromagnetic (FM) nearest-neighbor (J1=-1) exchange and frustrating antiferromagnetic (AFM) next-nearest-neighbor (J2>0) and next-next-nearest-neighbor (J3>0) exchanges, for the case J3=J2. We use the coupled cluster method in high orders of approximation, complemented by the exact diagonalization of a lattice with 32 sites, and calculate the gs energy, magnetic order parameter, and spin-spin correlation functions. We find a quantum phase transition between regions characterized by FM order and a form of AFM ("striped") collinear order at Jc2 ≈ 0.1095 0.0005. We compare results for the FM case (with J1=-1) to previous results for the corresponding AFM case (with J1=+1). While the magnetic order parameters behave similarly for the FM and the AFM models for large values of the frustration parameter J2, there are considerable differences between them for J2/|J1| 0.6. For example, the quasiclassical collinear magnetic long-range order for the AFM model (with J1=+1) breaks down at Jc22 ≈ 0.60, whereas the "equivalent" point for the FM model (with J1=-1) occurs at Jc2 ≈ 0.11. Unlike in the AFM model (with J1=+1), where a plaquette valence-bond crystal phase intrudes between the two corresponding quasiclassical AFM phases (with N\'eel and striped order) for Jc12 < J2 < Jc22, with Jc12 ≈ 0.47, we find no clear indications in the FM model for an intermediate magnetically disordered phase between the phases exhibiting FM and striped order. Instead, the evidence points strongly to a direct first-order transition between the two ordered phases of the FM model.