In this paper, we study the emergence of a Landauer transport regime from the quantum-mechanical dynamics of free electrons in a disordered tight-binding chain, which is coupled to finite leads with open boundaries. Both partitioned and partition-free initial conditions are analyzed and seen to give rise, for large enough leads, to the same spatially uniform quasisteady-state current, which agrees with the Landauer value. The quasisteady-state regime is preceded by a transient regime, which lasts for a time proportional to the length of the disordered sample, and followed by recursions, after a time that is proportional to the lead size. These theoretical predictions may be of interest to future experiments on transport of fermionic ultracold atoms across optical lattices. We also observe finite-size current oscillations, superimposed on the quasisteady state, whose behavior depends crucially on the conditions initially imposed on the system. Finally, we show how a time-resolved Kubo formula is able to reproduce this Landauer transport regime, as the leads grow bigger.

• Received 8 October 2019
• Revised 10 March 2020
• Accepted 11 March 2020

DOI:https://doi.org/10.1103/PhysRevB.101.104203