Fingerprint Acquisition Based on Photo‐Thermal Coloration of MoO 3 Ceramic upon the Irradiation of Multiband Light outside the Bandgap

Fingerprint Acquisition Based on Photo‐Thermal Coloration of MoO 3 Ceramic upon the Irradiation of Multiband Light outside the Bandgap

Fingerprints acquisition for identity recognition is extensively studied as a high requirement of the development of fingerprint acquisition technology. The photochromism of MoO 3 is widely reported upon ultraviolet light irradiation inside the bandgap, and if the photochromism can be achieved outsi...

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Veröffentlicht in:Advanced materials technologies 2020-11, Vol.5 (11)
Hauptverfasser: Li, Mingjun, Yang, Zhengwen, Wen, Yugeng, Ruan, Jiufeng, Ren, Youtao, Qiu, Jianbei, Song, Zhiguo, Wang, Yuehui, Liu, Bitao
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container_issue 11
container_start_page
container_title Advanced materials technologies
container_volume 5
creator Li, Mingjun
Yang, Zhengwen
Wen, Yugeng
Ruan, Jiufeng
Ren, Youtao
Qiu, Jianbei
Song, Zhiguo
Wang, Yuehui
Liu, Bitao
description Fingerprints acquisition for identity recognition is extensively studied as a high requirement of the development of fingerprint acquisition technology. The photochromism of MoO 3 is widely reported upon ultraviolet light irradiation inside the bandgap, and if the photochromism can be achieved outside the bandgap, then the discoloration adjustment can be more diversified and the application range will be wider. However, there are no report of the photochromism of MoO 3 upon the irradiation of multiband light outside bandgap. Herein, the MoO 3 ceramic is prepared by the solid‐state reaction, and its photochromism is investigated upon the irradiation of multiband light outside the bandgap. The colors of MoO 3 ceramic change from grey to dark blue upon the 473, 532, 808, or 980 nm laser irradiation, and the dark blue of MoO 3 ceramic is bleached upon thermal stimulation. The photochromic mechanism of MoO 3 ceramic is attributed to the laser‐induced heat effect. For the first time, fingerprint acquisition is obtained by means of the photo‐thermal‐chromism of MoO 3 ceramic. The cycle experiment demonstrates that the fingerprint acquisition based on the photo‐thermal‐chromism of MoO 3 has excellent repeatability and stability. These results suggest that this technology is nondestructive and repeatable, opening up a new approach for fingerprint acquisition.
doi_str_mv 10.1002/admt.202000562
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The photochromism of MoO 3 is widely reported upon ultraviolet light irradiation inside the bandgap, and if the photochromism can be achieved outside the bandgap, then the discoloration adjustment can be more diversified and the application range will be wider. However, there are no report of the photochromism of MoO 3 upon the irradiation of multiband light outside bandgap. Herein, the MoO 3 ceramic is prepared by the solid‐state reaction, and its photochromism is investigated upon the irradiation of multiband light outside the bandgap. The colors of MoO 3 ceramic change from grey to dark blue upon the 473, 532, 808, or 980 nm laser irradiation, and the dark blue of MoO 3 ceramic is bleached upon thermal stimulation. The photochromic mechanism of MoO 3 ceramic is attributed to the laser‐induced heat effect. For the first time, fingerprint acquisition is obtained by means of the photo‐thermal‐chromism of MoO 3 ceramic. The cycle experiment demonstrates that the fingerprint acquisition based on the photo‐thermal‐chromism of MoO 3 has excellent repeatability and stability. 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The cycle experiment demonstrates that the fingerprint acquisition based on the photo‐thermal‐chromism of MoO 3 has excellent repeatability and stability. These results suggest that this technology is nondestructive and repeatable, opening up a new approach for fingerprint acquisition.</abstract><doi>10.1002/admt.202000562</doi><orcidid>https://orcid.org/0000-0001-6470-9244</orcidid></addata></record>
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title Fingerprint Acquisition Based on Photo‐Thermal Coloration of MoO 3 Ceramic upon the Irradiation of Multiband Light outside the Bandgap
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