Static and dynamic structure factors in the Haldane phase of the bilinear-biquadratic spin-1

TL;DR

This paper investigates the static and dynamic structure factors in the Haldane phase of the one-dimensional spin-1 Heisenberg model with bilinear and biquadratic interactions, revealing excitation spectra and their evolution across different coupling regimes.

Contribution

It provides a detailed analysis of excitation spectra and structure factors in the Haldane phase, including the effects of varying the coupling parameter and identifying bound states and scattering continua.

Findings

Magnon states dominate at the VBS point.

Two-magnon and two-spinon excitations are characterized.

Excitation energies at specific momenta are independent of system size.

Abstract

The excitation spectra of the T=0 dynamic structure factors for the spin, dimer, and trimer fluctuation operators as well as for the newly defined center fluctuation operator in the one-dimensional S=1 Heisenberg model wi th isotropic bilinear $(J\cos\theta)$ and biquadratic $(J\sin\theta)$ exchange are investigated via the recursion method for systems with up to N=18 site s over the predicted range, $-\pi/4<\theta\lesssim\pi/4$, of the topologically ordered Haldane phase. The four static and dynamic structure factors probe t he ordering tendencies in the various coupling regimes and the elementary and composite excitations which dominate the T=0 dynamics. At $\theta = \arctan{1/3}$ (VBS point), the dynamically relevant spectra in the invariant subspaces with total spin $S_T = 0,1,2$ are dominated by a branch of magnon states $(S_T = 1)$, by continua of two-magnon scattering states $(S_T = 0,1,2)$, and by discrete branches of two-magnon bound states with positive interaction energy $(S_T = 0,2)$. The dimer and trimer spectra at $q=\pi$ ar e found to consist of single modes with $N$-independent excitation energies $\omega_\lambda^D/|e_0|=5$ and $\omega_\lambda^T/|e_0|=6$, where $e_0=E_0/N$ is the ground-state energy per site. The basic structure of the dynamically relevant excitation spectrum remains the same over a substantial parameter range within the Haldane phase. At the transition to the dimerized phase ($\theta=-\pi/4$), the two-magnon excitations turn into two-spinon excitations.