Multilevel Absorbers via the Integration of Undoped and Tungsten-Doped Multilayered Vanadium Dioxide Thin Films

Reconfigurable light absorbers have attracted much attention by providing additional optical responses and expanding the number of degrees of freedom in security applications. Fabry–Pèrot absorbers based on phase change materials with tunable properties can be implemented over large scales without...

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Veröffentlicht in:	ACS applied materials & interfaces 2022-01, Vol.14 (1), p.1404-1412
Hauptverfasser:	Ko, Byoungsu, Chae, Ji-Yeon, Badloe, Trevon, Kim, Hongyoon, Kim, Soo-Jung, Hong, Sung-Hoon, Paik, Taejong, Rho, Junsuk
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Schlagworte:	Functional Inorganic Materials and Devices
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creator	Ko, Byoungsu Chae, Ji-Yeon Badloe, Trevon Kim, Hongyoon Kim, Soo-Jung Hong, Sung-Hoon Paik, Taejong Rho, Junsuk
description	Reconfigurable light absorbers have attracted much attention by providing additional optical responses and expanding the number of degrees of freedom in security applications. Fabry–Pèrot absorbers based on phase change materials with tunable properties can be implemented over large scales without the need for additional steps such as lithography, while exhibiting reconfigurable optical responses. However, a fundamental limitation of widely used phase change materials such as vanadium dioxide and germanium–antimony–tellurium-based chalcogenide glasses is that they have only two distinct phases; therefore, only two different states of optical properties are available. Here, we experimentally demonstrate active multilevel absorbers that are tuned by controlling the external temperature. This is produced by creating large-scale lithography-free multilayer structures with both undoped and tungsten-doped solution-processed monoclinic-phase vanadium dioxide thin films. The doping of vanadium dioxide with tungsten allows for the modulation of the phase-transition temperature, which results in an extra degree of freedom and therefore an additional step for the tunable properties. The proposed multilevel absorber is designed and characterized both numerically and experimentally. Such large-scale multilevel tunable absorbers realized with nanoparticle-based solution fabrication techniques are expected to open the way for advanced thermo-optical cryptographic devices based on tunable reflective coloration and near-infrared absorption.
doi_str_mv	10.1021/acsami.1c19223
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The doping of vanadium dioxide with tungsten allows for the modulation of the phase-transition temperature, which results in an extra degree of freedom and therefore an additional step for the tunable properties. The proposed multilevel absorber is designed and characterized both numerically and experimentally. 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Mater. Interfaces</addtitle><date>2022-01-12</date><risdate>2022</risdate><volume>14</volume><issue>1</issue><spage>1404</spage><epage>1412</epage><pages>1404-1412</pages><issn>1944-8244</issn><eissn>1944-8252</eissn><abstract>Reconfigurable light absorbers have attracted much attention by providing additional optical responses and expanding the number of degrees of freedom in security applications. Fabry–Pèrot absorbers based on phase change materials with tunable properties can be implemented over large scales without the need for additional steps such as lithography, while exhibiting reconfigurable optical responses. However, a fundamental limitation of widely used phase change materials such as vanadium dioxide and germanium–antimony–tellurium-based chalcogenide glasses is that they have only two distinct phases; therefore, only two different states of optical properties are available. 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title	Multilevel Absorbers via the Integration of Undoped and Tungsten-Doped Multilayered Vanadium Dioxide Thin Films
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