Thermal Drude weight in an integrable chiral clock model

Abstract

We calculate the finite temperature thermal conductivity of a time-reversal invariant chiral Z3 clock model along an integrable line in the parameter space using tDMRG. The thermal current itself is not a conserved charge, unlike in the XXZ model, but has a finite overlap with a local conserved charge Q(2) obtained from the transfer matrix. We find that the Drude weight is finite at non-zero temperature, and the Mazur bound from Q(2) saturates the Drude weight, allowing us to obtain an asymptotic expression for the Drude weight at high temperatures. The numerical estimates are validated using a sum rule for thermal conductivity. On the computational side, we also explore the effectiveness of the ancilla disentangler in the integrable and non-integrable regimes of the model. We find that the disentangler helps in localizing the entanglement growth around the quench location, but the improvement is lesser in the non-integrable regime and at low temperatures.