Dynamical properties of the S=12 random Heisenberg chain

Abstract

We use numerical techniques to study dynamical properties at finite temperature (T) of the Heisenberg spin chain with random exchange couplings, which realizes the random singlet (RS) fixed point in the low-energy limit. Specifically, we study the dynamic spin structure factor S(q,ω), which can be probed directly by inelastic neutron scattering experiments and, in the limit of small ω, in nuclear magnetic resonance (NMR) experiments through the spin-lattice relaxation rate 1/T1. Our work combines three complementary methods: exact diagonalization, matrix-product-state algorithms, and stochastic analytic continuation of quantum Monte Carlo results in imaginary time. Unlike the uniform system, whose low-energy excitations at low T are restricted to q close to 0 and π, our study reveals a continuous narrow band of low-energy excitations in S(q,ω), extending throughout the Brillouin zone. Close to q=π, the scaling properties of these excitations are well captured by the RS theory, but we also see disagreements with some aspects of the predicted q-dependence further away from q=π. Furthermore we find spin diffusion effects close to q=0 that are not contained within the RS theory but give non-negligible contributions to the mean 1/T1. To compare with NMR experiments, we consider the distribution of the local 1/T1 values, which is broad, approximately described by a stretched exponential. The mean value first decreases with T, but starts to increase and diverge below a crossover temperature. Although a similar divergent behavior has been found for the static uniform susceptibility, this divergent behavior of 1/T1 has never been seen in experiments. Our results show that the divergence of the mean 1/T1 is due to rare events in the disordered chains and is concealed in experiments, where the typical 1/T1 value is accessed.