Tunable Nanophotonic Materials for Multispectral Reconfigurability

Yujie Luo; Thomas Christensen; Ognjen Ilic

doi:10.1364/NOMA.2024.NoTh1D.2

Tunable Nanophotonic Materials for Multispectral Reconfigurability

Yujie Luo
, Thomas Christensen
, Ognjen Ilic

University of Minnesota Twin Cities

Research output: Contribution to conference › Conference abstract for conference › Research › peer-review

Abstract

We show that active metasurface networks can accurately emulate and switch between complex spectral profiles, such as those of gases. This multispectral reconfigurability applies to coupled networks in active materials, including 2D or phase-change materials.

Original language	English
Publication date	2024
Number of pages	2
DOIs	https://doi.org/10.1364/NOMA.2024.NoTh1D.2
Publication status	Published - 2024
Event	2024 Novel Optical Materials and Applications - Quebec City, Canada Duration: 28 Jul 2024 → 1 Aug 2024

Conference

Conference	2024 Novel Optical Materials and Applications
Country/Territory	Canada
City	Quebec City
Period	28/07/2024 → 01/08/2024

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10.1364/NOMA.2024.NoTh1D.2

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title = "Tunable Nanophotonic Materials for Multispectral Reconfigurability",

abstract = "We show that active metasurface networks can accurately emulate and switch between complex spectral profiles, such as those of gases. This multispectral reconfigurability applies to coupled networks in active materials, including 2D or phase-change materials.",

author = "Yujie Luo and Thomas Christensen and Ognjen Ilic",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s); 2024 Novel Optical Materials and Applications, NOMA 2024 ; Conference date: 28-07-2024 Through 01-08-2024",

year = "2024",

doi = "10.1364/NOMA.2024.NoTh1D.2",

language = "English",

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TY - ABST

T1 - Tunable Nanophotonic Materials for Multispectral Reconfigurability

AU - Luo, Yujie

AU - Christensen, Thomas

AU - Ilic, Ognjen

PY - 2024

Y1 - 2024

N2 - We show that active metasurface networks can accurately emulate and switch between complex spectral profiles, such as those of gases. This multispectral reconfigurability applies to coupled networks in active materials, including 2D or phase-change materials.

AB - We show that active metasurface networks can accurately emulate and switch between complex spectral profiles, such as those of gases. This multispectral reconfigurability applies to coupled networks in active materials, including 2D or phase-change materials.

U2 - 10.1364/NOMA.2024.NoTh1D.2

DO - 10.1364/NOMA.2024.NoTh1D.2

M3 - Conference abstract for conference

AN - SCOPUS:85215998481

T2 - 2024 Novel Optical Materials and Applications

Y2 - 28 July 2024 through 1 August 2024

ER -

Tunable Nanophotonic Materials for Multispectral Reconfigurability

Abstract

Conference

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