Spin dynamics and continuum spectra of the honeycomb J1-J2 antiferromagnetic Heisenberg model
Abstract
We employ the spin cluster perturbation theory to investigate the dynamical properties of the antiferromagnetic J1-J2 Heisenberg model on the honeycomb lattice. We obtain the excitation spectra for all possible phases in the phase diagram, including the N\'eel phase, plaquette valence-bond-solid phase, dimer valence-bond-solid phase and stripe antiferromagnetic phase. In the N\'eel phase, besides the obvious renormalization of the magnon dispersion, we find that the spectrum exhibits a dome-shaped broad continuum around the second Brillouin zone (BZ) and the additional strong continuum close to the corner of the BZ. In the valence-bond-solid phases, the spectra are dominated by a strong broad continuum all the way down to below J1 coexisting with the lowest-energy triplon modes characterizing the plaquette and dimer phases. We ascribe this strong broad continuum and the additional continuum close to the BZ corner in the N\'eel phase to the contributions of fractionalized spinon excitations. In the stripe phase, a clear difference from the linear spin wave approximation is that the spectrum is gapped at the M point while that obtained by the latter is gapless due to the strong quantum fluctuations. We point out that the features observed in the N\'eel phase are consistent with the recent neutron scattering experiments on YbCl3 and YbBr3.
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