Finite-size anomalies of the Drude weight: role of symmetries and ensembles

Abstract

We revisit the subtelties of computing the high temperature spin stiffness D of the spin-1/2 XXZ chain using exact diagonalization to analyze its dependence on system symmetries and ensemble. Within the canonical ensemble and for states with zero magnetization, we find D vanishes exactly due to spin-inversion symmetry for all but the anisotropies MN = (π M /N) with N > M and coprime, provided system sizes L 2N, for which states with different spin-inversion signature become degenerate due to the underlying sl2 loop algebra symmetry. All these loop-algebra degenerate states carry finite currents which we conjecture [based on L and anisotropies MN (with N<L/2) available to us] to dominate the grand-canonical ensemble evaluation of D in the thermodynamic limit. Including a magnetic flux not only breaks spin-inversion in the zero magnetization sector but also lifts the loop-algebra degeneracies in all symmetry sectors --- this effect is more pertinent at smaller due to the larger contributions to D coming from the low-magnetization sectors which are more sensitive to the system's symmetries. Thus we generically find a finite D for fluxed rings and arbitrary 0<<1 in both ensembles. In contrast, at the isotropic point and in the gapped phase ( 1) D is found to vanish in the thermodynamic limit, independent of symmetry or ensemble. Our analysis demonstrates how convergence to the thermodynamic limit within the gapless phase ( < 1) may be accelerated and the finite-size anomalies overcome: D extrapolates nicely in the thermodynamic limit to either the recently computed lower-bound or the Thermodynamic Bethe Ansatz result provided both spin-inversion is broken and the additional degeneracies at the MN anisotropies are lifted.