Nonlocality in photonic materials and metamaterials: roadmap

Francesco Monticone; N. Asger Mortensen; Antonio I. Fernández-Domínguez; Yu Luo; Xuezhi Zheng; Christos Tserkezis; Jacob B. Khurgin; Tigran V. Shahbazyan; André J. Chaves; Nuno M.R. Peres; Gino Wegner; Kurt Busch; Huatian Hu; Fabio della Sala; Pu Zhang; Cristian Ciracì; Javier Aizpurua; Antton Babaze; Andrei G. Borisov; Xue Wen Chen; Thomas Christensen; Wei Yan; Yi Yang; Ulrich Hohenester; Lorenz Huber; Martijn Wubs; Simone de Liberato; P. A.D. Gonçalves; F. Javier García de Abajo; Ortwin Hess; Illya Tarasenko; Joel D. Cox; Line Jelver; Eduardo J.C. Dias; Miguel Sánchez Sánchez; Dionisios Margetis; Guillermo Gómez-Santos; Igor M. Vasilevskiy; Tobias Stauber; Sergei Tretyakov; Constantin Simovski; Samaneh Pakniyat; J. Sebastián Gómez-Díaz; Igor V. Bondarev; Svend Age Biehs; Alexandra Boltasseva; Vladimir M. Shalaev; Alexey V. Krasavin; Anatoly V. Zayats; Andrea Alù; Jung Hwan Song; Mark L. Brongersma; Uriel Levy; Olivia Y. Long; Cheng Guo; Shanhui Fan; Sergey I. Bozhevolnyi; Adam Overvig; Filipa R. Prudêncio; Mário G. Silveirinha; S. Ali Hassani Gangaraj; Christos Argyropoulos; Paloma A. Huidobro; Emanuele Galiffi; Fan Yang; John B. Pendry; David A.B. Miller

doi:10.1364/ome.559374

Nonlocality in photonic materials and metamaterials: roadmap

Francesco Monticone^*
, N. Asger Mortensen
, Antonio I. Fernández-Domínguez
, Yu Luo
, Xuezhi Zheng
, Christos Tserkezis
, Jacob B. Khurgin
, Tigran V. Shahbazyan
, André J. Chaves
, Nuno M.R. Peres
, Gino Wegner
, Kurt Busch
, Huatian Hu
, Fabio della Sala
, Pu Zhang
, Cristian Ciracì
, Javier Aizpurua
, Antton Babaze
, Andrei G. Borisov
, Xue Wen Chen

Thomas Christensen, Wei Yan, Yi Yang, Ulrich Hohenester, Lorenz Huber, Martijn Wubs, Simone de Liberato, P. A.D. Gonçalves, F. Javier García de Abajo, Ortwin Hess, Illya Tarasenko, Joel D. Cox, Line Jelver, Eduardo J.C. Dias, Miguel Sánchez Sánchez, Dionisios Margetis, Guillermo Gómez-Santos, Igor M. Vasilevskiy, Tobias Stauber, Sergei Tretyakov, Constantin Simovski, Samaneh Pakniyat, J. Sebastián Gómez-Díaz, Igor V. Bondarev, Svend Age Biehs, Alexandra Boltasseva, Vladimir M. Shalaev, Alexey V. Krasavin, Anatoly V. Zayats, Andrea Alù, Jung Hwan Song, Mark L. Brongersma, Uriel Levy, Olivia Y. Long, Cheng Guo, Shanhui Fan, Sergey I. Bozhevolnyi, Adam Overvig, Filipa R. Prudêncio, Mário G. Silveirinha, S. Ali Hassani Gangaraj, Christos Argyropoulos, Paloma A. Huidobro, Emanuele Galiffi, Fan Yang, John B. Pendry, David A.B. Miller

^*Corresponding author for this work

Cornell University
University of Southern Denmark
Universidad Autónoma de Madrid
Nanyang Technological University
KU Leuven
Johns Hopkins University
Jackson State University
Max-Born-Institute for Nonlinear Optics and Short Pulse Spectroscopy
Humboldt University of Berlin
Italian Institute of Technology
Huazhong University of Science and Technology
University of the Basque Country
Donostia International Physics Center
University of Graz
University of Southampton
ICFO - Institute of Photonic Sciences
Trinity College Dublin
CSIC - Institute of Materials Science in Madrid
University of Maryland, College Park
Aalto University
University of California at Davis
North Carolina Central University
University of Oldenburg
Purdue University
King's College London
City University of New York
National University of Singapore
Stanford University
Hebrew University of Jerusalem
Stevens Institute of Technology
University of Lisbon
Corning Incorporated
Pennsylvania State University
Sichuan University
Imperial College London

Research output: Contribution to journal › Journal article › Research › peer-review

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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.

Original language	English
Journal	Optical Materials Express
Volume	15
Issue number	7
Pages (from-to)	1544-1709
ISSN	2159-3930
DOIs	https://doi.org/10.1364/ome.559374
Publication status	Published - 2025

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Monticone, F., Mortensen, N. A., Fernández-Domínguez, A. I., Luo, Y., Zheng, X., Tserkezis, C., Khurgin, J. B., Shahbazyan, T. V., Chaves, A. J., Peres, N. M. R., Wegner, G., Busch, K., Hu, H., della Sala, F., Zhang, P., Ciracì, C., Aizpurua, J., Babaze, A., Borisov, A. G., ... Miller, D. A. B. (2025). Nonlocality in photonic materials and metamaterials: roadmap. Optical Materials Express, 15(7), 1544-1709. https://doi.org/10.1364/ome.559374

@article{6e7135a0166040e9b638b241f48fa036,

title = "Nonlocality in photonic materials and metamaterials: roadmap",

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.",

author = "Francesco Monticone and Mortensen, \{N. Asger\} and Fern{\'a}ndez-Dom{\'i}nguez, \{Antonio I.\} and Yu Luo and Xuezhi Zheng and Christos Tserkezis and Khurgin, \{Jacob B.\} and Shahbazyan, \{Tigran V.\} and Chaves, \{Andr{\'e} J.\} and Peres, \{Nuno M.R.\} and Gino Wegner and Kurt Busch and Huatian Hu and \{della Sala\}, Fabio and Pu Zhang and Cristian Cirac{\`i} and Javier Aizpurua and Antton Babaze and Borisov, \{Andrei G.\} and Chen, \{Xue Wen\} and Thomas Christensen and Wei Yan and Yi Yang and Ulrich Hohenester and Lorenz Huber and Martijn Wubs and \{de Liberato\}, Simone and Gon{\c c}alves, \{P. A.D.\} and \{de Abajo\}, \{F. Javier Garc{\'i}a\} and Ortwin Hess and Illya Tarasenko and Cox, \{Joel D.\} and Line Jelver and Dias, \{Eduardo J.C.\} and S{\'a}nchez, \{Miguel S{\'a}nchez\} and Dionisios Margetis and Guillermo G{\'o}mez-Santos and Vasilevskiy, \{Igor M.\} and Tobias Stauber and Sergei Tretyakov and Constantin Simovski and Samaneh Pakniyat and G{\'o}mez-D{\'i}az, \{J. Sebasti{\'a}n\} and Bondarev, \{Igor V.\} and Biehs, \{Svend Age\} and Alexandra Boltasseva and Shalaev, \{Vladimir M.\} and Krasavin, \{Alexey V.\} and Zayats, \{Anatoly V.\} and Andrea Al{\`u} and Song, \{Jung Hwan\} and Brongersma, \{Mark L.\} and Uriel Levy and Long, \{Olivia Y.\} and Cheng Guo and Shanhui Fan and Bozhevolnyi, \{Sergey I.\} and Adam Overvig and Prud{\^e}ncio, \{Filipa R.\} and Silveirinha, \{M{\'a}rio G.\} and Gangaraj, \{S. Ali Hassani\} and Christos Argyropoulos and Huidobro, \{Paloma A.\} and Emanuele Galiffi and Fan Yang and Pendry, \{John B.\} and Miller, \{David A.B.\}",

note = "Publisher Copyright: Journal {\textcopyright} 2025.",

year = "2025",

doi = "10.1364/ome.559374",

language = "English",

volume = "15",

pages = "1544--1709",

journal = "Optical Materials Express",

issn = "2159-3930",

publisher = "Optica Publishing Group (formerly OSA)",

number = "7",

}

Monticone, F, Mortensen, NA, Fernández-Domínguez, AI, Luo, Y, Zheng, X, Tserkezis, C, Khurgin, JB, Shahbazyan, TV, Chaves, AJ, Peres, NMR, Wegner, G, Busch, K, Hu, H, della Sala, F, Zhang, P, Ciracì, C, Aizpurua, J, Babaze, A, Borisov, AG, Chen, XW, Christensen, T , Yan, W, Yang, Y, Hohenester, U, Huber, L, Wubs, M, de Liberato, S, Gonçalves, PAD, de Abajo, FJG, Hess, O, Tarasenko, I, Cox, JD, Jelver, L, Dias, EJC, Sánchez, MS, Margetis, D, Gómez-Santos, G, Vasilevskiy, IM, Stauber, T, Tretyakov, S, Simovski, C, Pakniyat, S, Gómez-Díaz, JS, Bondarev, IV, Biehs, SA, Boltasseva, A, Shalaev, VM, Krasavin, AV, Zayats, AV, Alù, A, Song, JH, Brongersma, ML, Levy, U, Long, OY, Guo, C, Fan, S, Bozhevolnyi, SI, Overvig, A, Prudêncio, FR, Silveirinha, MG, Gangaraj, SAH, Argyropoulos, C, Huidobro, PA, Galiffi, E, Yang, F, Pendry, JB & Miller, DAB 2025, 'Nonlocality in photonic materials and metamaterials: roadmap', Optical Materials Express, vol. 15, no. 7, pp. 1544-1709. https://doi.org/10.1364/ome.559374

TY - JOUR

T1 - Nonlocality in photonic materials and metamaterials

T2 - roadmap

AU - Monticone, Francesco

AU - Mortensen, N. Asger

AU - Fernández-Domínguez, Antonio I.

AU - Luo, Yu

AU - Zheng, Xuezhi

AU - Tserkezis, Christos

AU - Khurgin, Jacob B.

AU - Shahbazyan, Tigran V.

AU - Chaves, André J.

AU - Peres, Nuno M.R.

AU - Wegner, Gino

AU - Busch, Kurt

AU - Hu, Huatian

AU - della Sala, Fabio

AU - Zhang, Pu

AU - Ciracì, Cristian

AU - Aizpurua, Javier

AU - Babaze, Antton

AU - Borisov, Andrei G.

AU - Chen, Xue Wen

AU - Christensen, Thomas

AU - Yan, Wei

AU - Yang, Yi

AU - Hohenester, Ulrich

AU - Huber, Lorenz

AU - Wubs, Martijn

AU - de Liberato, Simone

AU - Gonçalves, P. A.D.

AU - de Abajo, F. Javier García

AU - Hess, Ortwin

AU - Tarasenko, Illya

AU - Cox, Joel D.

AU - Jelver, Line

AU - Dias, Eduardo J.C.

AU - Sánchez, Miguel Sánchez

AU - Margetis, Dionisios

AU - Gómez-Santos, Guillermo

AU - Vasilevskiy, Igor M.

AU - Stauber, Tobias

AU - Tretyakov, Sergei

AU - Simovski, Constantin

AU - Pakniyat, Samaneh

AU - Gómez-Díaz, J. Sebastián

AU - Bondarev, Igor V.

AU - Biehs, Svend Age

AU - Boltasseva, Alexandra

AU - Shalaev, Vladimir M.

AU - Krasavin, Alexey V.

AU - Zayats, Anatoly V.

AU - Alù, Andrea

AU - Song, Jung Hwan

AU - Brongersma, Mark L.

AU - Levy, Uriel

AU - Long, Olivia Y.

AU - Guo, Cheng

AU - Fan, Shanhui

AU - Bozhevolnyi, Sergey I.

AU - Overvig, Adam

AU - Prudêncio, Filipa R.

AU - Silveirinha, Mário G.

AU - Gangaraj, S. Ali Hassani

AU - Argyropoulos, Christos

AU - Huidobro, Paloma A.

AU - Galiffi, Emanuele

AU - Yang, Fan

AU - Pendry, John B.

AU - Miller, David A.B.

PY - 2025

Y1 - 2025

N2 - 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.

AB - 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.

U2 - 10.1364/ome.559374

DO - 10.1364/ome.559374

M3 - Journal article

AN - SCOPUS:105011186075

SN - 2159-3930

VL - 15

SP - 1544

EP - 1709

JO - Optical Materials Express

JF - Optical Materials Express

IS - 7

ER -

Nonlocality in photonic materials and metamaterials: roadmap

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