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Autori principali: Sidorenko, Anna, Giesen, Jan Mathis, Eggert, Sebastian, Linden, Stefan
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2603.00227
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author Sidorenko, Anna
Giesen, Jan Mathis
Eggert, Sebastian
Linden, Stefan
author_facet Sidorenko, Anna
Giesen, Jan Mathis
Eggert, Sebastian
Linden, Stefan
contents We present a joint experimental and theoretical study of a ratchet implemented in arra ys of evanescently coupled plasmonic waveguides with tailored losses. In this setup the time-periodic dissipation is the only active mechanism and notably, we find better rectified transport and lower losses in the transmitted signal with increased local dissipation. Using Floquet theory, we uncover a driving regime that allows efficient directional tr ansport for suitable driving frequencies and loss rates, which are linked to linear qu asienergy bands with minimal losses. These regions are separated from non-resonant beh avior by sharp transitions with characteristic exceptional points in the spectrum. Direct experimental observation of the Floquet-dissipative ratchet effect using a comb ination of real- and Fourier-space leakage radiation microscopy is provided.
format Preprint
id arxiv_https___arxiv_org_abs_2603_00227
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Tailored dissipation for directional transport in plasmonic ratchets
Sidorenko, Anna
Giesen, Jan Mathis
Eggert, Sebastian
Linden, Stefan
Optics
Mesoscale and Nanoscale Physics
Quantum Physics
We present a joint experimental and theoretical study of a ratchet implemented in arra ys of evanescently coupled plasmonic waveguides with tailored losses. In this setup the time-periodic dissipation is the only active mechanism and notably, we find better rectified transport and lower losses in the transmitted signal with increased local dissipation. Using Floquet theory, we uncover a driving regime that allows efficient directional tr ansport for suitable driving frequencies and loss rates, which are linked to linear qu asienergy bands with minimal losses. These regions are separated from non-resonant beh avior by sharp transitions with characteristic exceptional points in the spectrum. Direct experimental observation of the Floquet-dissipative ratchet effect using a comb ination of real- and Fourier-space leakage radiation microscopy is provided.
title Tailored dissipation for directional transport in plasmonic ratchets
topic Optics
Mesoscale and Nanoscale Physics
Quantum Physics
url https://arxiv.org/abs/2603.00227