Abstract
We study nonlinear Drude weights (NLDWs) for the spin-1/2 XXZ chain in the critical regime at zero temperature. The NLDWs are generalizations of the linear Drude weight. Via the nonlinear extension of the Kohn formula, they can be read off from higher-order finite-size corrections to the ground-state energy in the presence of a $U(1)$ magnetic flux. The analysis of the ground-state energy based on the Bethe ansatz reveals that the NLDWs exhibit convergence, power-law, and logarithmic divergence, depending on the anisotropy parameter $\Delta$. We determine the convergent and power-law divergent regions, which depend on the order of the response $n$. Then, we examine the behavior of the NLDWs at the boundary between the two regions and find that they converge for $n=0, 1, 2$ $({\rm mod}~4)$, while they show logarithmic divergence for $n=3$ $({\rm mod}~4)$. Furthermore, we identify particular anisotropies $\Delta=\cos(\pi r/(r+1))$ ($r=1,2, 3,\ldots$) at which the NLDW at any order $n$ converges to a finite value.
Highlights
Transport phenomena have been a subject of central interest in condensed matter physics
IV, we review the origin of the divergences of the nonlinear Drude weight (NLDW) and carefully determine the convergent and divergent regions
In order to calculate the NLDWs, we investigated the finite-size corrections to the ground-state energy of the chain with U (1) flux and revealed that its finitesize scaling was quite distinct depending on the anisotropy parameter
Summary
Transport phenomena have been a subject of central interest in condensed matter physics. The origin of these divergences was identified as nonanalytic finite-size corrections to the ground-state energy [16] This property was discussed except when the anisotropy parameter takes special. Since higherorder ones have wider divergent regions, some of the special anisotropies are surrounded by the divergent region We confirm this discontinuous behavior in the critical regime by calculating one of the higher-order NLDWs numerically. Numerical confirmation of the scaling for several anisotropies is given there
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