Zero-frequency transport properties of one-dimensional spin-$\frac{1}{2}$ systems

We report a detailed analysis of the Drude weights for both thermal and spin transport in one-dimensional spin-$\frac{1}{2}$ systems by means of exact diagonalization and analytic approaches at finite temperatures. Transport properties are studied first for the integrable $\mathrm{XXZ}$ model and second for various nonintegrable systems such as the dimerized chain, the frustrated chain, and the spin ladder. We compare our results obtained by exact diagonalization and mean-field theory with those of the Bethe ansatz, bosonization, and other numerical studies in the case of the anisotropic Heisenberg model both in the gapless and gapped regime. In particular, we find indications that the Drude weight for spin transport is finite in the thermodynamic limit for the isotropic chain. For the nonintegrable models, a finite-size analysis of the numerical data for the Drude weights is presented, covering the entire parameter space of the dimerized and frustrated chain. We also discuss which conclusions can be drawn from bosonization regarding the question of whether the Drude weights are finite or not. One of our main results is that the Drude weights vanish in the thermodynamic limit for nonintegrable models.