Persistent currents by reservoir engineering

TL;DR

This paper shows that persistent currents can be generated in quantum systems through reservoir engineering, using structured environments and non-reciprocal dynamics, without external gauge fields.

Contribution

It introduces a method to induce persistent currents via dissipative reservoir engineering in many-body quantum systems, extending non-reciprocal Lindblad dynamics to this context.

Findings

Persistent currents are achievable solely through dissipative effects.

Steady-state currents persist in large systems.

Currents remain robust under perturbations.

Abstract

We demonstrate that persistent currents can be induced in a quantum system in contact with a structured reservoir, without the need of any applied gauge field. The working principle of the mechanism leading to their presence is based on the extension to the many-body scenario of non-reciprocal Lindblad dynamics, recently put forward by Metelmann and Clerk in Phys. Rev. X 5, 021025 (2015): Non-reciprocity can be generated by suitably balancing coherent interactions with their corresponding dissipative version, induced by the coupling to a common structured environment, such to make total interactions directional. Specifically, we consider an interacting spin/boson model in a ring-shaped one-dimensional lattice coupled to an external bath. By employing a combination of cluster mean-field, exact diagonalization and matrix-product-operator techniques, we show that solely dissipative effects suffice to engineer steady states with a persistent current that survives in the limit of large systems. We also verify the robustness of such current in the presence of additional dissipative or Hamiltonian perturbation terms.