Heat conductivity of the Heisenberg spin-1/2 ladder: From weak to strong breaking of integrability

TL;DR

This paper provides a comprehensive analysis of heat conductivity in Heisenberg spin-1/2 ladders across all inter-chain couplings and temperatures, revealing scaling laws and the connection between weak and strong coupling regimes.

Contribution

It demonstrates the validity of perturbative predictions over a wide parameter range and uncovers the scaling behavior of heat conductivity in different coupling limits.

Findings

Perturbative prediction $\,rac{ ext{J}_ot^{-2}}{ ext{valid in a wide range}}$

Power-law scaling $\,rac{ ext{J}_ot^{2}}{ ext{at large }J_ot$

Broad minimum in $\,rac{ ext{conductivity}}{ ext{at intermediate }J_ot$

Abstract

We investigate the heat conductivity $\kappa$ of the Heisenberg spin-1/2 ladder at finite temperature covering the entire range of inter-chain coupling $J_\perp$, by using several numerical methods and perturbation theory within the framework of linear response. We unveil that a perturbative prediction $\kappa \propto J_\perp^{-2}$, based on simple golden-rule arguments and valid in the strict limit $J_\perp \to 0$, applies to a remarkably wide range of $J_\perp$, qualitatively and quantitatively. In the large $J_\perp$-limit, we show power-law scaling of opposite nature, namely, $\kappa \propto J_\perp^2$. Moreover, we demonstrate the weak and strong coupling regimes to be connected by a broad minimum, slightly below the isotropic point at $J_\perp = J_\parallel$. As a function of temperature $T$, this minimum scales as $\kappa \propto T^{-2}$ down to $T$ on the order of the exchange coupling constant. These results provide for a comprehensive picture of $\kappa(J_\perp,T)$ of spin ladders.