Effect of perturbations on the kagome S=1/2 antiferromagnet at all temperatures

Abstract

The ground state of the S=1/2 kagome Heisenberg antiferromagnet is now recognized as a spin liquid, but its precise nature remains unsettled, even if more and more clues point towards a gapless spin liquid. We use high temperature series expansions (HTSE) to extrapolate the specific heat cV(T) and the magnetic susceptibility (T) over the full temperature range, using an improved entropy method with a self-determination of the ground state energy per site e0. Optimized algorithms give the HTSE coefficients up to unprecedented orders (20 in 1/T) and as exact functions of the magnetic field. Three extrapolations are presented for different low-T behaviors of cV: exponential (for a gapped system), linear or quadratic (for two different types of gapless spin liquids). We study the effects of various perturbations to the Heisenberg Hamiltonian: Ising anisotropy, Dzyaloshinskii-Moriya interactions, second and third neighbor interactions, and randomly distributed magnetic vacancies. We propose an experimental determination of (T=0), which could be non zero, from cV measurements under different magnetic fields.