Effect of local charge fluctuations on spin physics in the Neel state of La2CuO4
Abstract
We explore the effect of local charge fluctuations on the spin response of a Mott insulator by deriving an effective spin model, and studying it using Schwinger boson mean field theory. Applying this to La2CuO4, we show that an accurate fit to the magnon dispersion relation, measured by Coldea et al. [Phys. Rev. Lett. 86, 5377 (2001)] is obtained with Hubbard model parameters U ≈ 2.34 eV, and t ≈ 360 meV. These parameters lead to estimates of the staggered magnetization (ms ≈ 0.25), spin wave velocity (c≈ 800 meV-), and spin stiffness (s ≈ 24 meV). In particular the staggered moment as well as the effective local moment are renormalized to smaller values compared to the Heisenberg model due to local charge fluctuations in the Hubbard model. The dynamical structure factor shows considerable weight in the continuum along the zone boundary as well as secondary peaks that may be observed in high resolution neutron scattering experiments.
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