Topological insulator metamaterials
Topological insulator metamaterials
Confinement of electromagnetic fields at the subwavelength scale via metamaterial paradigms is an established method to engineer light–matter interaction in most common material systems, from insulators to semiconductors and from metals to superconductors. In recent years, this approach has been extended to the realm of topological materials, providing a new avenue to access nontrivial features of their electronic band structure. In this review, we survey various topological material classes from a photonics standpoint, including crystal growth and lithographic structuring methods. We discuss how exotic electronic features such as spin-selective Dirac plasmon polaritons in topological insulators or hyperbolic plasmon polaritons in Weyl semimetals may give rise to unconventional magneto-optic, nonlinear, and circular photogalvanic effects in metamaterials across the visible to infrared spectrum. Finally, we dwell on how these effects may be dynamically controlled by applying external perturbations in the form of electric and magnetic fields or ultrafast optical pulses. Through these examples and future perspectives, we argue that topological insulator, semimetal and superconductor metamaterials are unique systems to bridge the missing links between nanophotonic, electronic, and spintronic technologies.
4416–4442
Krishnamoorthy, Harish N. S.
87456c53-9077-4ccf-80b9-44470ad845b9
Dubrovkin, Alexander M.
2ea62d64-614e-4416-9d6c-7347217a8c88
Adamo, Giorgio
73480dbd-5d3e-415a-b569-9606b3dbeecc
Soci, Cesare
38b2dc9e-77d4-4e3e-9308-40ee93d61e7a
21 March 2023
Krishnamoorthy, Harish N. S.
87456c53-9077-4ccf-80b9-44470ad845b9
Dubrovkin, Alexander M.
2ea62d64-614e-4416-9d6c-7347217a8c88
Adamo, Giorgio
73480dbd-5d3e-415a-b569-9606b3dbeecc
Soci, Cesare
38b2dc9e-77d4-4e3e-9308-40ee93d61e7a
Krishnamoorthy, Harish N. S., Dubrovkin, Alexander M., Adamo, Giorgio and Soci, Cesare
(2023)
Topological insulator metamaterials.
Chemical Reviews, 123 (8), .
(doi:10.1021/acs.chemrev.2c00594).
Abstract
Confinement of electromagnetic fields at the subwavelength scale via metamaterial paradigms is an established method to engineer light–matter interaction in most common material systems, from insulators to semiconductors and from metals to superconductors. In recent years, this approach has been extended to the realm of topological materials, providing a new avenue to access nontrivial features of their electronic band structure. In this review, we survey various topological material classes from a photonics standpoint, including crystal growth and lithographic structuring methods. We discuss how exotic electronic features such as spin-selective Dirac plasmon polaritons in topological insulators or hyperbolic plasmon polaritons in Weyl semimetals may give rise to unconventional magneto-optic, nonlinear, and circular photogalvanic effects in metamaterials across the visible to infrared spectrum. Finally, we dwell on how these effects may be dynamically controlled by applying external perturbations in the form of electric and magnetic fields or ultrafast optical pulses. Through these examples and future perspectives, we argue that topological insulator, semimetal and superconductor metamaterials are unique systems to bridge the missing links between nanophotonic, electronic, and spintronic technologies.
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Published date: 21 March 2023
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Local EPrints ID: 509593
URI: http://eprints.soton.ac.uk/id/eprint/509593
ISSN: 0009-2665
PURE UUID: f839de66-4e75-4f8c-ac37-8cd6fa044869
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Date deposited: 26 Feb 2026 17:38
Last modified: 26 Feb 2026 17:38
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Contributors
Author:
Harish N. S. Krishnamoorthy
Author:
Alexander M. Dubrovkin
Author:
Giorgio Adamo
Author:
Cesare Soci
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