Deep learning enabled strategies for modeling of complex aperiodic plasmonic metasurfaces of arbitrary size
Deep learning enabled strategies for modeling of complex aperiodic plasmonic metasurfaces of arbitrary size
Optical interactions have an important impact on the optical response of nanostructures in complex environments. Accounting for interactions in large ensembles of structures requires computationally demanding numerical calculations. In particular, if no periodicity can be exploited, full field simulations can become prohibitively expensive. Here we propose a method for the numerical description of aperiodic assemblies of plasmonic nanostructures. Our approach is based on dressed polarizabilities, which are conventionally very expensive to calculate, a problem which we alleviate using a deep convolutional neural network as surrogate model. We demonstrate that the method offers high accuracy with errors in the order of a percent. In cases where the interactions are predominantly short-range (e.g., for out-of-plane illumination of planar metasurfaces), it can be used to describe aperiodic metasurfaces of basically unlimited size, containing many thousands of unordered plasmonic nanostructures. We furthermore show that the model is capable to spectrally resolve coupling effects. The approach is therefore of the highest interest for the field of metasurfaces. It provides significant advantages in applications like homogenization of large aperiodic planar metastructures or the design of sophisticated wavefronts at the micrometer scale, where optical interactions play a crucial role.
deep learning, nanophotonics, nonperiodic nanostructures, plasmonic metasurfaces, rapid nano-optics simulations
575-585
Majorel, Clément
bca99fb2-8377-4617-9322-ae0e5f379809
Girard, Christian
95dbb625-105f-4ae1-b1dd-02b1fa33d708
Arbouet, Arnaud
3c681c1a-31cf-45dc-9f7f-604b81ebde4e
Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Wiecha, Peter R.
fb335482-9577-41af-a0ef-3988b7654c9b
16 February 2022
Majorel, Clément
bca99fb2-8377-4617-9322-ae0e5f379809
Girard, Christian
95dbb625-105f-4ae1-b1dd-02b1fa33d708
Arbouet, Arnaud
3c681c1a-31cf-45dc-9f7f-604b81ebde4e
Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Wiecha, Peter R.
fb335482-9577-41af-a0ef-3988b7654c9b
Majorel, Clément, Girard, Christian, Arbouet, Arnaud, Muskens, Otto L. and Wiecha, Peter R.
(2022)
Deep learning enabled strategies for modeling of complex aperiodic plasmonic metasurfaces of arbitrary size.
ACS Photonics, 9 (2), .
(doi:10.1021/acsphotonics.1c01556).
Abstract
Optical interactions have an important impact on the optical response of nanostructures in complex environments. Accounting for interactions in large ensembles of structures requires computationally demanding numerical calculations. In particular, if no periodicity can be exploited, full field simulations can become prohibitively expensive. Here we propose a method for the numerical description of aperiodic assemblies of plasmonic nanostructures. Our approach is based on dressed polarizabilities, which are conventionally very expensive to calculate, a problem which we alleviate using a deep convolutional neural network as surrogate model. We demonstrate that the method offers high accuracy with errors in the order of a percent. In cases where the interactions are predominantly short-range (e.g., for out-of-plane illumination of planar metasurfaces), it can be used to describe aperiodic metasurfaces of basically unlimited size, containing many thousands of unordered plasmonic nanostructures. We furthermore show that the model is capable to spectrally resolve coupling effects. The approach is therefore of the highest interest for the field of metasurfaces. It provides significant advantages in applications like homogenization of large aperiodic planar metastructures or the design of sophisticated wavefronts at the micrometer scale, where optical interactions play a crucial role.
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acsphotonics.1c01556
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e-pub ahead of print date: 18 January 2022
Published date: 16 February 2022
Keywords:
deep learning, nanophotonics, nonperiodic nanostructures, plasmonic metasurfaces, rapid nano-optics simulations
Identifiers
Local EPrints ID: 468076
URI: http://eprints.soton.ac.uk/id/eprint/468076
ISSN: 2330-4022
PURE UUID: 70d30394-e4dd-42fc-bd65-f0581d3e0189
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Date deposited: 29 Jul 2022 16:56
Last modified: 17 Mar 2024 03:18
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Contributors
Author:
Clément Majorel
Author:
Christian Girard
Author:
Arnaud Arbouet
Author:
Peter R. Wiecha
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