Active Optical Metasurfaces Based on Defect-Engineered Phase-Transition Materials

Jura Rensberg; Shuyan Zhang; You Zhou; Alexander S. McLeod; Christian Schwarz; Michael Goldflam; Mengkun Liu; Jochen Kerbusch; Ronny Nawrodt; Shriram Ramanathan; D. N. Basov; Federico Capasso; Carsten Ronning; Mikhail A. Kats

doi:10.1021/acs.nanolett.5b04122

Active Optical Metasurfaces Based on Defect-Engineered Phase-Transition Materials

Jura Rensberg, Shuyan Zhang, You Zhou, Alexander S. McLeod, Christian Schwarz, Michael Goldflam, Mengkun Liu, Jochen Kerbusch, Ronny Nawrodt, Shriram Ramanathan, D. N. Basov, Federico Capasso, Carsten Ronning, Mikhail A. Kats

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187 Scopus citations

Abstract

Active, widely tunable optical materials have enabled rapid advances in photonics and optoelectronics, especially in the emerging field of meta-devices. Here, we demonstrate that spatially selective defect engineering on the nanometer scale can transform phase-transition materials into optical metasurfaces. Using ion irradiation through nanometer-scale masks, we selectively defect-engineered the insulator-metal transition of vanadium dioxide, a prototypical correlated phase-transition material whose optical properties change dramatically depending on its state. Using this robust technique, we demonstrated several optical metasurfaces, including tunable absorbers with artificially induced phase coexistence and tunable polarizers based on thermally triggered dichroism. Spatially selective nanoscale defect engineering represents a new paradigm for active photonic structures and devices.

Original language	English (US)
Pages (from-to)	1050-1055
Number of pages	6
Journal	Nano letters
Volume	16
Issue number	2
DOIs	https://doi.org/10.1021/acs.nanolett.5b04122
State	Published - Feb 10 2016
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2015 American Chemical Society.

Keywords

Metasurfaces
defect engineering
meta-devices
metamaterials
phase-transition materials

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abstract = "Active, widely tunable optical materials have enabled rapid advances in photonics and optoelectronics, especially in the emerging field of meta-devices. Here, we demonstrate that spatially selective defect engineering on the nanometer scale can transform phase-transition materials into optical metasurfaces. Using ion irradiation through nanometer-scale masks, we selectively defect-engineered the insulator-metal transition of vanadium dioxide, a prototypical correlated phase-transition material whose optical properties change dramatically depending on its state. Using this robust technique, we demonstrated several optical metasurfaces, including tunable absorbers with artificially induced phase coexistence and tunable polarizers based on thermally triggered dichroism. Spatially selective nanoscale defect engineering represents a new paradigm for active photonic structures and devices.",

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AU - Rensberg, Jura

AU - Zhang, Shuyan

AU - Zhou, You

AU - McLeod, Alexander S.

AU - Schwarz, Christian

AU - Goldflam, Michael

AU - Liu, Mengkun

AU - Kerbusch, Jochen

AU - Nawrodt, Ronny

AU - Ramanathan, Shriram

AU - Basov, D. N.

AU - Capasso, Federico

AU - Ronning, Carsten

AU - Kats, Mikhail A.

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AB - Active, widely tunable optical materials have enabled rapid advances in photonics and optoelectronics, especially in the emerging field of meta-devices. Here, we demonstrate that spatially selective defect engineering on the nanometer scale can transform phase-transition materials into optical metasurfaces. Using ion irradiation through nanometer-scale masks, we selectively defect-engineered the insulator-metal transition of vanadium dioxide, a prototypical correlated phase-transition material whose optical properties change dramatically depending on its state. Using this robust technique, we demonstrated several optical metasurfaces, including tunable absorbers with artificially induced phase coexistence and tunable polarizers based on thermally triggered dichroism. Spatially selective nanoscale defect engineering represents a new paradigm for active photonic structures and devices.

KW - Metasurfaces

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Active Optical Metasurfaces Based on Defect-Engineered Phase-Transition Materials

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