Subwavelength asymmetric Au-VO2 nanodisk dimer for switchable directional scattering

Han Mou Zhang; Wu Yun Shang; Hua Lu; Fa Jun Xiao; Jian Lin Zhao

doi:10.1088/1674-1056/27/11/117301

Subwavelength asymmetric Au-VO₂ nanodisk dimer for switchable directional scattering

Han Mou Zhang, Wu Yun Shang, Hua Lu, Fa Jun Xiao, Jian Lin Zhao

School of Physical Science and Technology

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

We propose an asymmetric Au-VO₂ nanodisk dimer for realizing a switchable directional scattering. Specifically, the directional scattering can be triggered on/off through controlling the phase transition of the VO₂ nanodisk from metallic to semiconductor state. More strikingly, an obvious directional scattering with the directivity of ~ 40 dB is achieved under the metallic state of VO₂ nanodisk. This tunable directional scattering is further explained with an interference model where the Au and VO₂ nanodisks are treated as two weakly interacting electric dipoles. The phase transition controlled scattering patterns of asymmetric Au-VO₂ nanodisk dimer are then well interpreted from the phase difference between these two dipoles.

Original language	English
Article number	117301
Journal	Chinese Physics B
Volume	27
Issue number	11
DOIs	https://doi.org/10.1088/1674-1056/27/11/117301
State	Published - 2018

Keywords

Directional scattering
Localized surface plasmon resonance
Vanadium dioxide

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10.1088/1674-1056/27/11/117301

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title = "Subwavelength asymmetric Au-VO2 nanodisk dimer for switchable directional scattering",

abstract = "We propose an asymmetric Au-VO2 nanodisk dimer for realizing a switchable directional scattering. Specifically, the directional scattering can be triggered on/off through controlling the phase transition of the VO2 nanodisk from metallic to semiconductor state. More strikingly, an obvious directional scattering with the directivity of ~ 40 dB is achieved under the metallic state of VO2 nanodisk. This tunable directional scattering is further explained with an interference model where the Au and VO2 nanodisks are treated as two weakly interacting electric dipoles. The phase transition controlled scattering patterns of asymmetric Au-VO2 nanodisk dimer are then well interpreted from the phase difference between these two dipoles.",

keywords = "Directional scattering, Localized surface plasmon resonance, Vanadium dioxide",

author = "Zhang, {Han Mou} and Shang, {Wu Yun} and Hua Lu and Xiao, {Fa Jun} and Zhao, {Jian Lin}",

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T1 - Subwavelength asymmetric Au-VO2 nanodisk dimer for switchable directional scattering

AU - Zhang, Han Mou

AU - Shang, Wu Yun

AU - Lu, Hua

AU - Xiao, Fa Jun

AU - Zhao, Jian Lin

PY - 2018

Y1 - 2018

N2 - We propose an asymmetric Au-VO2 nanodisk dimer for realizing a switchable directional scattering. Specifically, the directional scattering can be triggered on/off through controlling the phase transition of the VO2 nanodisk from metallic to semiconductor state. More strikingly, an obvious directional scattering with the directivity of ~ 40 dB is achieved under the metallic state of VO2 nanodisk. This tunable directional scattering is further explained with an interference model where the Au and VO2 nanodisks are treated as two weakly interacting electric dipoles. The phase transition controlled scattering patterns of asymmetric Au-VO2 nanodisk dimer are then well interpreted from the phase difference between these two dipoles.

AB - We propose an asymmetric Au-VO2 nanodisk dimer for realizing a switchable directional scattering. Specifically, the directional scattering can be triggered on/off through controlling the phase transition of the VO2 nanodisk from metallic to semiconductor state. More strikingly, an obvious directional scattering with the directivity of ~ 40 dB is achieved under the metallic state of VO2 nanodisk. This tunable directional scattering is further explained with an interference model where the Au and VO2 nanodisks are treated as two weakly interacting electric dipoles. The phase transition controlled scattering patterns of asymmetric Au-VO2 nanodisk dimer are then well interpreted from the phase difference between these two dipoles.

KW - Directional scattering

KW - Localized surface plasmon resonance

KW - Vanadium dioxide

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DO - 10.1088/1674-1056/27/11/117301

M3 - 文章

AN - SCOPUS:85057535504

SN - 1674-1056

VL - 27

JO - Chinese Physics B

JF - Chinese Physics B

IS - 11

M1 - 117301

ER -

Subwavelength asymmetric Au-VO₂ nanodisk dimer for switchable directional scattering

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