Abstract:
We have investigated the thermal conductivity κmag of high-purity single crystals of the spin chain compound Sr2CuO3, which is considered an excellent realization of the one-dimensional spin-1/2 antiferromagnetic Heisenberg model. We find that the spinon heat conductivity κmag is strongly enhanced as compared to previous results obtained on samples with lower chemical purity. The analysis of κmag allows the computation of the spinon mean free path lmag as a function of temperature. At low temperature we find lmag ~ 0.5 µm, corresponding to more than 1200 chain unit cells. Upon increasing the temperature, the mean free path decreases strongly and approaches an exponential decay ~ (1/T)exp(Tu*/T), which is characteristic for Umklapp processes with the energy scale kBTu*. Based on Matthiessen's rule we decompose lmag into a temperature-independent spinon–defect scattering length l0 and a temperature-dependent spinon–phonon scattering length lsp(T). By comparing lmag(T) of Sr2CuO3 with that of SrCuO2, we show that the spin–phonon interaction, as expressed by lsp, is practically the same in both systems. The comparison of the empirically derived lsp with model calculations for the spin–phonon interaction of the one-dimensional spin-1/2 XY model yields reasonable agreement with the experimental data.