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Thouless Pumping in a Driven-Dissipative Kerr Resonator Array

Sylvain Ravets, Nicolas Pernet, Nader Mostaan, Nathan Goldman, J. Bloch

2025Physical Review Letters16 citationsDOI

Abstract

Thouless pumping is an emblematic manifestation of topology in physics, referring to the ability to induce a quantized transport of charge across a system by simply varying one of its parameters periodically in time. The original concept of Thouless pumping involves a noninteracting system, and has been implemented in several platforms. One current challenge in the field is to extend this concept to interacting systems. In this Letter, we propose a Thouless pump that solely relies on nonlinear physics, within a chain of coupled Kerr resonators. Leveraging the driven-dissipative nature of the system, we modulate in space and time the on-site Kerr interaction energies, and generate 1+1-dimensional topological bands in the Bogoliubov spectrum of excitations. These bands present the same topology as the ones obtained within the Harper-Hofstadter framework, and the Wannier states associated to each band experience a net displacement and show quantized transport according to the band Chern numbers. Remarkably, we find driving configurations leading to band inversion, revealing an interaction-induced topological transition. Our numerical simulations are performed using realistic parameters inspired from exciton polaritons, which form a platform of choice for investigating driven topological phases of matter.

Topics & Concepts

Dissipative systemResonatorPhysicsOpticsQuantum mechanicsStrong Light-Matter InteractionsCold Atom Physics and Bose-Einstein CondensatesNonlinear Photonic Systems
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