Anomalous and regular transport in spin 1/2 chains: AC conductivity

TL;DR

This paper investigates magnetization transport in the integrable and perturbed XXZ spin-1/2 chain model at high temperatures, revealing super-diffusive behavior, sensitivity to perturbation signs, and the effects of integrability-breaking terms on AC conductivity.

Contribution

It provides a detailed analysis of AC conductivity and transport regimes in the XXZ model with and without integrability-breaking perturbations, highlighting new sensitivity effects and transport behaviors.

Findings

Super-diffusion at the isotropic point with frequency-dependent conductivity.

Sensitivity of conductivity to the sign of perturbations, especially $J_2$.

Observation of sub-diffusion and hydrodynamic relaxation due to perturbations.

Abstract

We study magnetization transport in anisotropic spin-$1/2$ chains governed by the integrable XXZ model with and without integrability-breaking perturbations at high temperatures ($T\to \infty$) using a hybrid approach that combines exact sum-rules with judiciously chosen Ans\"atze. In the integrable XXZ model we find (i) super-diffusion at the isotropic (Heisenberg) point, with frequency dependent conductivity $ \sigma'(\omega\to 0) \sim |\omega|^{\alpha}$, where $\alpha=-3/7$ in close numerical agreement with recent $t$-DMRG computations; (ii) a continuously drifting exponent from $\alpha=-1^+$ in the XY limit of the model to $\alpha>0$ within the Ising regime; and (iii) a diffusion constant saturating in the XY coupling deep in the Ising limit. We consider two kinds of integrability breaking perturbations --- a simple next-nearest-neighbor spin-flip term ($J_2$) and a three-spin assisted variant ($t_2$), natural in the fermion particle representation of the spin chain. In the first case we discover a remarkable sensitivity of $\sigma'(\omega)$ to the sign of $J_2$, with enhanced low frequency spectral weight and a pronounced upward shift in the magnitude of $\alpha$ for $J_2>0$. Perhaps even more surprising, we find sub-diffusion ($\alpha>0$) over a range of $J_2<0$. By contrast, the effects of the \enquote{fermionic} three-spin perturbation are sign symmetric; this perturbation produces a clearly observable hydrodynamic relaxation. At large strength of the integrability breaking term $J_2\to \pm \infty$ the problem is effectively non-interacting (fermions hopping on odd and even sublattices) and we find $\alpha\to -1$ behavior reminiscent of the XY limit of the XXZ chain. Exact diagonalization studies largely corroborate these findings at mid-frequencies.