Thermoplasmonic controlled optical absorber based on a liquid crystal metasurface
Thermoplasmonic controlled optical absorber based on a liquid crystal metasurface
Metasurfaces can be realized by organizing subwavelength elements (e.g., plasmonic nanoparticles) on a reflective surface covered with a dielectric layer. Such an array of resonators, acting collectively, can completely absorb the resulting resonant wavelength. Unfortunately, despite the excellent optical properties of metasurfaces, they lack the tunability to perform as adaptive optical components. To boost the utilization of metasurfaces and realize a new generation of dynamically controlled optical components, we report our recent finding based on the powerful combination of an innovative metasurface-optical absorber and nematic liquid crystals (NLCs). The metasurface consists of self-assembled silver nanocubes (AgNCs) immobilized on a 50 nm thick gold layer by using a polyelectrolyte multilayer as a dielectric spacer. The resulting optical absorbers show a well-defined reflection band centered in the near-infrared of the electromagnetic spectrum (750–770 nm), a very high absorption efficiency (∼60%) at the resonant wavelength, and an elevated photothermal efficiency estimated from the time constant value (34 s). Such a metasurface-based optical absorber, combined with an NLC layer, planarly aligned via a photoaligned top cover glass substrate, shows homogeneous NLC alignment and an absorption band photothermally tunable over approximately 46 nm. Detailed thermographic studies and spectroscopic investigations highlight the extraordinary capability of the active metasurface to be used as a light-controllable optical absorber.
Thermoplasmonics, active control, colloidal nanoparticles, liquid crystal, lithography-free, metasurface, liquid crystals, thermoplasmonics
49468-49477
Petronella, Francesca
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Madeleine, Tristan
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De Mei, Vincenzo
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Zaccagnini, Federica
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Striccoli, Marinella
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D'alessandro, Giampaolo
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Rumi, Mariacristina
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Slagle, Jonathan
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Kaczmarek, Malgosia
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de Sio, Luciano
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10 October 2023
Petronella, Francesca
fd797e8c-3f08-4fe4-a4f8-4d7c9d0ea628
Madeleine, Tristan
7a9d1327-0a94-4e8c-9003-d80f1778db54
De Mei, Vincenzo
0ff045ea-b1ac-4a9f-9f8d-5c5a18a7e7a6
Zaccagnini, Federica
d345b752-b8fe-417d-b472-a4899aac52ae
Striccoli, Marinella
b5c4edc2-a2f9-4fea-8f3c-ad9ddda1a60b
D'alessandro, Giampaolo
bad097e1-9506-4b6e-aa56-3e67a526e83b
Rumi, Mariacristina
c19e225a-81d8-4a4a-8795-0c9e2edebdc7
Slagle, Jonathan
379da3b5-ebd8-4468-907e-198f0a547221
Kaczmarek, Malgosia
408ec59b-8dba-41c1-89d0-af846d1bf327
de Sio, Luciano
b99c029d-ff49-43bf-8fdc-5089e1031bfd
Petronella, Francesca, Madeleine, Tristan, De Mei, Vincenzo, Zaccagnini, Federica, Striccoli, Marinella, D'alessandro, Giampaolo, Rumi, Mariacristina, Slagle, Jonathan, Kaczmarek, Malgosia and de Sio, Luciano
(2023)
Thermoplasmonic controlled optical absorber based on a liquid crystal metasurface.
ACS Applied Materials and Interfaces, 15 (42), .
(doi:10.1021/acsami.3c09896).
Abstract
Metasurfaces can be realized by organizing subwavelength elements (e.g., plasmonic nanoparticles) on a reflective surface covered with a dielectric layer. Such an array of resonators, acting collectively, can completely absorb the resulting resonant wavelength. Unfortunately, despite the excellent optical properties of metasurfaces, they lack the tunability to perform as adaptive optical components. To boost the utilization of metasurfaces and realize a new generation of dynamically controlled optical components, we report our recent finding based on the powerful combination of an innovative metasurface-optical absorber and nematic liquid crystals (NLCs). The metasurface consists of self-assembled silver nanocubes (AgNCs) immobilized on a 50 nm thick gold layer by using a polyelectrolyte multilayer as a dielectric spacer. The resulting optical absorbers show a well-defined reflection band centered in the near-infrared of the electromagnetic spectrum (750–770 nm), a very high absorption efficiency (∼60%) at the resonant wavelength, and an elevated photothermal efficiency estimated from the time constant value (34 s). Such a metasurface-based optical absorber, combined with an NLC layer, planarly aligned via a photoaligned top cover glass substrate, shows homogeneous NLC alignment and an absorption band photothermally tunable over approximately 46 nm. Detailed thermographic studies and spectroscopic investigations highlight the extraordinary capability of the active metasurface to be used as a light-controllable optical absorber.
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petronella-et-al-2023-thermoplasmonic-controlled-optical-absorber-based-on-a-liquid-crystal-metasurface
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More information
Accepted/In Press date: 22 September 2023
Published date: 10 October 2023
Additional Information:
Funding Information:
This work has been supported by the Air Force Office of Scientific Research, Air Force Material Command, U.S. Air Force, “Digital optical network encryption with liquid-crystal grating metasurface perfect absorbers” (FA8655-22-1-7007) (P. I. L. De Sio, EOARD 2022–2025), by the PHC Galilée 2022 “Photo-thermal therapy of melanoma cancer cells via antibody functionalized biomassderived carbon nanodots” (G22_63), and by the Leverhulme Trust “DiG for the Future: Taming disorder in self-assembled materials with topology” (grant RPG-2019-055).
Publisher Copyright:
© 2023 The Authors. Published by American Chemical Society.
Keywords:
Thermoplasmonics, active control, colloidal nanoparticles, liquid crystal, lithography-free, metasurface, liquid crystals, thermoplasmonics
Identifiers
Local EPrints ID: 483168
URI: http://eprints.soton.ac.uk/id/eprint/483168
ISSN: 1944-8244
PURE UUID: f8fffc2e-8ccc-4595-9ecf-15861d5ae4e0
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Date deposited: 25 Oct 2023 17:10
Last modified: 12 Nov 2024 03:03
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Contributors
Author:
Francesca Petronella
Author:
Vincenzo De Mei
Author:
Federica Zaccagnini
Author:
Marinella Striccoli
Author:
Mariacristina Rumi
Author:
Jonathan Slagle
Author:
Luciano de Sio
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