Multicolor Tunable Electrochromic Materials Based on the Burstein-Moss Effect

Multicolor Tunable Electrochromic Materials Based on the Burstein-Moss Effect

Inorganic electrochromic (EC) materials, which can reversibly switch their optical properties by current or potential, are at the forefront of commercialization of displays and smart windows. However, most inorganic EC materials have challenges in achieving multicolor tunability. Here, we propose th...

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Bibliographic Details
Published in:Nanomaterials (Basel, Switzerland) Vol. 13; no. 10; p. 1580
Main Authors: Zhou, Xia, Huang, Enhui, Zhang, Rui, Xiang, Hui, Zhong, Wenying, Xu, Bo
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 09-05-2023
MDPI
Subjects:
Burstein–Moss effect
Carrier density
Commercialization
electrochromic (EC) materials
Electrochromism
Energy
Identification and classification
Inorganic compounds
Light
multicolor tunable
Near infrared radiation
Optical properties
Semiconductors
Smart materials
Windows (apertures)
China
Burstein–Moss effect
electrochromic (EC) materials
multicolor tunable
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Summary:Inorganic electrochromic (EC) materials, which can reversibly switch their optical properties by current or potential, are at the forefront of commercialization of displays and smart windows. However, most inorganic EC materials have challenges in achieving multicolor tunability. Here, we propose that the Burstein-Moss (BM) effect, which could widen the optical gap by carrier density, could be a potential mechanism to realize the multicolor tunable EC phenomenon. Degenerated semiconductors with suitable fundament band gaps and effective carrier masses could be potential candidates for multicolor tunable EC materials based on the BM effect. We select bulk Y CF as an example to illustrate multicolor tunability based on the BM effect. In addition to multicolor tunability, the BM effect also could endow EC devices with the ability to selectively modulate the absorption for near infrared and visible light, but with a simpler device structure. Thus, we believe that this mechanism could be applied to design novel EC smart windows with unprecedented functions.
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ISSN:2079-4991
2079-4991
DOI:10.3390/nano13101580