Roadmap on nonlocality in photonic materials and metamaterials: nonlocality in polar dielectrics
Roadmap on nonlocality in photonic materials and metamaterials: nonlocality in polar dielectrics
Photonic technologies continue to drive the quest for new optical materials with unprecedented responses. A major frontier in this field is the exploration of nonlocal (spatially dispersive) materials, going beyond the local, wavevector-independent assumption traditionally adopted in optical material modeling. The growing interest in plasmonic, polaritonic, and quantum materials has revealed naturally occurring nonlocalities, emphasizing the need for more accurate models to predict and design their optical responses. This has major implications also for topological, nonreciprocal, and time-varying systems based on these material platforms. Beyond natural materials, artificially structured materials—metamaterials and metasurfaces—can provide even stronger and engineered nonlocal effects, emerging from long-range interactions or multipolar effects. This is a rapidly expanding area in the field of photonic metamaterials, with open frontiers yet to be explored. In metasurfaces, in particular, nonlocality engineering has emerged as a powerful tool for designing strongly wavevector-dependent responses, enabling enhanced wavefront control, spatial compression, multifunctional devices, and wave-based computing. Furthermore, nonlocality and related concepts play a critical role in defining the ultimate limits of what is possible in optics, photonics, and wave physics. This Roadmap aims to survey the most exciting developments in nonlocal photonic materials and metamaterials, highlight new opportunities and open challenges, and chart new pathways that will drive this emerging field forward—toward new scientific discoveries and technological advancements.
1544-1709
Monticone, Francesco
dcd956db-3d86-454b-b38a-81ba8fbf9b2f
Mortensen, N. Asger
917dc1fa-3e50-4dd9-8461-a8faa059eb9e
Fernández-Domínguez, Antonio I.
b93c0cb5-4e7a-462b-979e-f1077e392022
De Liberato, Simone
5942e45f-3115-4027-8653-a82667ed8473
18 June 2025
Monticone, Francesco
dcd956db-3d86-454b-b38a-81ba8fbf9b2f
Mortensen, N. Asger
917dc1fa-3e50-4dd9-8461-a8faa059eb9e
Fernández-Domínguez, Antonio I.
b93c0cb5-4e7a-462b-979e-f1077e392022
De Liberato, Simone
5942e45f-3115-4027-8653-a82667ed8473
Monticone, Francesco, Mortensen, N. Asger and Fernández-Domínguez, Antonio I.
,
et al.
(2025)
Roadmap on nonlocality in photonic materials and metamaterials: nonlocality in polar dielectrics.
Optical Materials Express, 15 (7), .
Abstract
Photonic technologies continue to drive the quest for new optical materials with unprecedented responses. A major frontier in this field is the exploration of nonlocal (spatially dispersive) materials, going beyond the local, wavevector-independent assumption traditionally adopted in optical material modeling. The growing interest in plasmonic, polaritonic, and quantum materials has revealed naturally occurring nonlocalities, emphasizing the need for more accurate models to predict and design their optical responses. This has major implications also for topological, nonreciprocal, and time-varying systems based on these material platforms. Beyond natural materials, artificially structured materials—metamaterials and metasurfaces—can provide even stronger and engineered nonlocal effects, emerging from long-range interactions or multipolar effects. This is a rapidly expanding area in the field of photonic metamaterials, with open frontiers yet to be explored. In metasurfaces, in particular, nonlocality engineering has emerged as a powerful tool for designing strongly wavevector-dependent responses, enabling enhanced wavefront control, spatial compression, multifunctional devices, and wave-based computing. Furthermore, nonlocality and related concepts play a critical role in defining the ultimate limits of what is possible in optics, photonics, and wave physics. This Roadmap aims to survey the most exciting developments in nonlocal photonic materials and metamaterials, highlight new opportunities and open challenges, and chart new pathways that will drive this emerging field forward—toward new scientific discoveries and technological advancements.
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Accepted/In Press date: 27 March 2025
Published date: 18 June 2025
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Local EPrints ID: 509222
URI: http://eprints.soton.ac.uk/id/eprint/509222
ISSN: 2159-3930
PURE UUID: e06d1bef-83c2-462d-8028-96ad805511a7
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Date deposited: 13 Feb 2026 17:38
Last modified: 14 Feb 2026 02:47
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Author:
Francesco Monticone
Author:
N. Asger Mortensen
Author:
Antonio I. Fernández-Domínguez
Corporate Author: et al.
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