Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice

Tony Mathew Blessan; Bastián Real; Camille Druelle; Clarisse Fournier; Alberto Muñoz de las Heras; Alejandro González-Tudela; Isabelle Sagnes; Abdelmounaim Harouri; Luc Le Gratiet; Aristide Lemaître; Sylvain Ravets; Jacqueline Bloch; Clément Hainaut; Alberto Amo

doi:10.1103/b3wk-r8r3

Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice

Tony Mathew Blessan
, Bastián Real
, Camille Druelle
, Clarisse Fournier
, Alberto Muñoz de las Heras
, Alejandro González-Tudela
, Isabelle Sagnes
, Abdelmounaim Harouri
, Luc Le Gratiet
, Aristide Lemaître
, Sylvain Ravets
, Jacqueline Bloch
, Clément Hainaut
, Alberto Amo

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Photonic lattices facilitate band structure engineering, supporting both localized and extended modes through their geometric design. However, greater control over these modes can be achieved by taking advantage of the interference effect between external drives with precisely tuned phases and photonic modes within the lattice. In this work, we build on this principle to demonstrate optical switching, directed light propagation, and site-specific localization in a one-dimensional photonic lattice of coupled microresonators by resonantly driving the system with a coherent field of controlled phase. Importantly, our experimental results provide direct evidence that increased driving power acts as a tuning parameter enabling nonlinear localization at frequencies previously inaccessible in the linear regime. These findings open different avenues for controlling light propagation and localization in lattices with more elaborate band structures.

langue originale	Anglais
Numéro d'article	033283
journal	Physical Review Research
Volume	7
Numéro de publication	3
Les DOIs	https://doi.org/10.1103/b3wk-r8r3
état	Publié - 1 juil. 2025
Modification externe	Oui

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10.1103/b3wk-r8r3

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Blessan, T. M., Real, B., Druelle, C., Fournier, C., Heras, A. M. D. L., González-Tudela, A., Sagnes, I., Harouri, A., Le Gratiet, L., Lemaître, A., Ravets, S., Bloch, J., Hainaut, C., & Amo, A. (2025). Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice. Physical Review Research, 7(3), Article 033283. https://doi.org/10.1103/b3wk-r8r3

@article{1d9ec7031f014ef890674daa0dcc52ab,

title = "Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice",

abstract = "Photonic lattices facilitate band structure engineering, supporting both localized and extended modes through their geometric design. However, greater control over these modes can be achieved by taking advantage of the interference effect between external drives with precisely tuned phases and photonic modes within the lattice. In this work, we build on this principle to demonstrate optical switching, directed light propagation, and site-specific localization in a one-dimensional photonic lattice of coupled microresonators by resonantly driving the system with a coherent field of controlled phase. Importantly, our experimental results provide direct evidence that increased driving power acts as a tuning parameter enabling nonlinear localization at frequencies previously inaccessible in the linear regime. These findings open different avenues for controlling light propagation and localization in lattices with more elaborate band structures.",

author = "Blessan, \{Tony Mathew\} and Basti{\'a}n Real and Camille Druelle and Clarisse Fournier and Heras, \{Alberto Mu{\~n}oz de las\} and Alejandro Gonz{\'a}lez-Tudela and Isabelle Sagnes and Abdelmounaim Harouri and \{Le Gratiet\}, Luc and Aristide Lema{\^i}tre and Sylvain Ravets and Jacqueline Bloch and Cl{\'e}ment Hainaut and Alberto Amo",

note = "Publisher Copyright: {\textcopyright} 2025 authors. Published by the American Physical Society.",

year = "2025",

month = jul,

day = "1",

doi = "10.1103/b3wk-r8r3",

language = "English",

volume = "7",

journal = "Physical Review Research",

issn = "2643-1564",

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Blessan, TM, Real, B, Druelle, C, Fournier, C, Heras, AMDL, González-Tudela, A, Sagnes, I, Harouri, A, Le Gratiet, L, Lemaître, A, Ravets, S, Bloch, J, Hainaut, C & Amo, A 2025, 'Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice', Physical Review Research, VOL. 7, Numéro 3, 033283. https://doi.org/10.1103/b3wk-r8r3

TY - JOUR

T1 - Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice

AU - Blessan, Tony Mathew

AU - Real, Bastián

AU - Druelle, Camille

AU - Fournier, Clarisse

AU - Heras, Alberto Muñoz de las

AU - González-Tudela, Alejandro

AU - Sagnes, Isabelle

AU - Harouri, Abdelmounaim

AU - Le Gratiet, Luc

AU - Lemaître, Aristide

AU - Ravets, Sylvain

AU - Bloch, Jacqueline

AU - Hainaut, Clément

AU - Amo, Alberto

PY - 2025/7/1

Y1 - 2025/7/1

N2 - Photonic lattices facilitate band structure engineering, supporting both localized and extended modes through their geometric design. However, greater control over these modes can be achieved by taking advantage of the interference effect between external drives with precisely tuned phases and photonic modes within the lattice. In this work, we build on this principle to demonstrate optical switching, directed light propagation, and site-specific localization in a one-dimensional photonic lattice of coupled microresonators by resonantly driving the system with a coherent field of controlled phase. Importantly, our experimental results provide direct evidence that increased driving power acts as a tuning parameter enabling nonlinear localization at frequencies previously inaccessible in the linear regime. These findings open different avenues for controlling light propagation and localization in lattices with more elaborate band structures.

AB - Photonic lattices facilitate band structure engineering, supporting both localized and extended modes through their geometric design. However, greater control over these modes can be achieved by taking advantage of the interference effect between external drives with precisely tuned phases and photonic modes within the lattice. In this work, we build on this principle to demonstrate optical switching, directed light propagation, and site-specific localization in a one-dimensional photonic lattice of coupled microresonators by resonantly driving the system with a coherent field of controlled phase. Importantly, our experimental results provide direct evidence that increased driving power acts as a tuning parameter enabling nonlinear localization at frequencies previously inaccessible in the linear regime. These findings open different avenues for controlling light propagation and localization in lattices with more elaborate band structures.

UR - https://www.scopus.com/pages/publications/105024868911

U2 - 10.1103/b3wk-r8r3

DO - 10.1103/b3wk-r8r3

M3 - Article

AN - SCOPUS:105024868911

SN - 2643-1564

VL - 7

JO - Physical Review Research

JF - Physical Review Research

IS - 3

M1 - 033283

ER -

Directional transport and nonlinear localization of light in a one-dimensional driven-dissipative photonic lattice

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