Nanoscale precision brings experimental metalens efficiencies on par with theoretical promises

Villads Egede Johansen; Uǧur Meriç Gür; Jade Martínez-Llinás; Jesper Fly Hansen; Akbar Samadi; Maria Skak Vestergaard Larsen; Theodor Nielsen; Fredrik Mattinson; Moritz Schmidlin; N. Asger Mortensen; Ulrich J. Quaade

doi:10.1038/s42005-024-01598-6

Nanoscale precision brings experimental metalens efficiencies on par with theoretical promises

Villads Egede Johansen, Uǧur Meriç Gür, Jade Martínez-Llinás, Jesper Fly Hansen, Akbar Samadi, Maria Skak Vestergaard Larsen, Theodor Nielsen, Fredrik Mattinson, Moritz Schmidlin, N. Asger Mortensen, Ulrich J. Quaade^*

^*Kontaktforfatter

Center for Polariton-driven Light-Matter Interactions (POLIMA)

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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Abstract

Metalenses are flat lenses, where sub-wavelength, so-called meta-atoms manipulate the electric field to perform a given lens function. Compared to traditional lenses, the two main drawbacks of metalenses are their achromatic limitations and low efficiencies. While an abundance of simulations show that efficiencies above 90% are attainable for low numerical apertures (NA), experimental reports showing such high efficiencies are limited. Here, we use electron-beam lithography (EBL) to realize a set of lenses with varying NA from 0.08 to 0.93. The low NAs were expected to fit the model, and the higher NAs determine the validity range of the model. We find that measured efficiencies above 92% for NA = 0.24 are achievable, and that a slight modification of the simulation model extends its validility to NA = 0.6. Based on our results, we discuss that the lower efficiencies reported in the literature are caused by low-fidelity manufacturing, closing the efficiency gap between measurements and simulation in metalens fabrication.

Originalsprog	Engelsk
Artikelnummer	123
Tidsskrift	Communications Physics
Vol/bind	7
Udgave nummer	1
Antal sider	7
ISSN	2399-3650
DOI	https://doi.org/10.1038/s42005-024-01598-6
Status	Udgivet - dec. 2024

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10.1038/s42005-024-01598-6Licens: CC BY

Open Access VersionForlagets udgivne version, 2,58 MBLicens: CC BY

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Tjek adgangen til materialet i Syddansk Universitetsbiblioteks søgemaskine

Citationsformater

Egede Johansen, V., Gür, U. M., Martínez-Llinás, J., Fly Hansen, J., Samadi, A., Skak Vestergaard Larsen, M., Nielsen, T., Mattinson, F., Schmidlin, M., Mortensen, N. A., & Quaade, U. J. (2024). Nanoscale precision brings experimental metalens efficiencies on par with theoretical promises. Communications Physics, 7(1), Artikel 123. https://doi.org/10.1038/s42005-024-01598-6

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title = "Nanoscale precision brings experimental metalens efficiencies on par with theoretical promises",

abstract = "Metalenses are flat lenses, where sub-wavelength, so-called meta-atoms manipulate the electric field to perform a given lens function. Compared to traditional lenses, the two main drawbacks of metalenses are their achromatic limitations and low efficiencies. While an abundance of simulations show that efficiencies above 90% are attainable for low numerical apertures (NA), experimental reports showing such high efficiencies are limited. Here, we use electron-beam lithography (EBL) to realize a set of lenses with varying NA from 0.08 to 0.93. The low NAs were expected to fit the model, and the higher NAs determine the validity range of the model. We find that measured efficiencies above 92% for NA = 0.24 are achievable, and that a slight modification of the simulation model extends its validility to NA = 0.6. Based on our results, we discuss that the lower efficiencies reported in the literature are caused by low-fidelity manufacturing, closing the efficiency gap between measurements and simulation in metalens fabrication.",

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doi = "10.1038/s42005-024-01598-6",

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T1 - Nanoscale precision brings experimental metalens efficiencies on par with theoretical promises

AU - Egede Johansen, Villads

AU - Gür, Uǧur Meriç

AU - Martínez-Llinás, Jade

AU - Fly Hansen, Jesper

AU - Samadi, Akbar

AU - Skak Vestergaard Larsen, Maria

AU - Nielsen, Theodor

AU - Mattinson, Fredrik

AU - Schmidlin, Moritz

AU - Mortensen, N. Asger

AU - Quaade, Ulrich J.

PY - 2024/12

Y1 - 2024/12

N2 - Metalenses are flat lenses, where sub-wavelength, so-called meta-atoms manipulate the electric field to perform a given lens function. Compared to traditional lenses, the two main drawbacks of metalenses are their achromatic limitations and low efficiencies. While an abundance of simulations show that efficiencies above 90% are attainable for low numerical apertures (NA), experimental reports showing such high efficiencies are limited. Here, we use electron-beam lithography (EBL) to realize a set of lenses with varying NA from 0.08 to 0.93. The low NAs were expected to fit the model, and the higher NAs determine the validity range of the model. We find that measured efficiencies above 92% for NA = 0.24 are achievable, and that a slight modification of the simulation model extends its validility to NA = 0.6. Based on our results, we discuss that the lower efficiencies reported in the literature are caused by low-fidelity manufacturing, closing the efficiency gap between measurements and simulation in metalens fabrication.

AB - Metalenses are flat lenses, where sub-wavelength, so-called meta-atoms manipulate the electric field to perform a given lens function. Compared to traditional lenses, the two main drawbacks of metalenses are their achromatic limitations and low efficiencies. While an abundance of simulations show that efficiencies above 90% are attainable for low numerical apertures (NA), experimental reports showing such high efficiencies are limited. Here, we use electron-beam lithography (EBL) to realize a set of lenses with varying NA from 0.08 to 0.93. The low NAs were expected to fit the model, and the higher NAs determine the validity range of the model. We find that measured efficiencies above 92% for NA = 0.24 are achievable, and that a slight modification of the simulation model extends its validility to NA = 0.6. Based on our results, we discuss that the lower efficiencies reported in the literature are caused by low-fidelity manufacturing, closing the efficiency gap between measurements and simulation in metalens fabrication.

U2 - 10.1038/s42005-024-01598-6

DO - 10.1038/s42005-024-01598-6

M3 - Journal article

AN - SCOPUS:85189933354

SN - 2399-3650

VL - 7

JO - Communications Physics

JF - Communications Physics

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ER -

Nanoscale precision brings experimental metalens efficiencies on par with theoretical promises

Abstract

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