Issue 23, 2024

A narrowband ultraviolet-B-emitting LiCaPO4:Gd3+ phosphor with super-long persistent luminescence for over 100 h

Abstract

The past decades have witnessed a significant increase in interest in inorganic luminescent materials that emit in the narrowband ultraviolet-B (NB-UVB; 310–313 nm) spectral region due to the growing need for applications in photochemistry and photomedicine. However, the majority of existing NB-UVB phosphors rely on photoluminescence, which requires constant external excitation. This common but inconvenient photoluminescence style significantly slows down the progress of NB-UVB luminescence technology. Herein, we report the design and synthesis of a new Gd3+-doped NB-UVB-emitting persistent phosphor, LiCaPO4:Gd3+, which shows strong NB-UVB persistent luminescence peaking at 312 nm and a super-long persistence time of >100 h after ceasing X-ray excitation. Owing to the zero-background noise from the ambient light, a UVB camera can detect the NB-UVB light emission originating from the charged LiCaPO4:Gd3+ phosphor in a bright indoor environment. Through spectroscopic investigations and first-principles calculations, the nature of energy traps and the persistent luminescence mechanism of Gd3+ in the LiCaPO4 host have been thoroughly studied. Besides, remarkable photochromic behavior when irradiating the phosphor with X-rays is also observed, and the possible intrinsic point defects that contribute to the colorization are proposed. This NB-UVB persistent phosphor shows great potential in indoor optical tagging, optical information storage, and dermatological therapy.

Graphical abstract: A narrowband ultraviolet-B-emitting LiCaPO4:Gd3+ phosphor with super-long persistent luminescence for over 100 h

Supplementary files

Article information

Article type
Research Article
Submitted
22 Sep 2024
Accepted
22 Oct 2024
First published
23 Oct 2024

Inorg. Chem. Front., 2024,11, 8314-8323

A narrowband ultraviolet-B-emitting LiCaPO4:Gd3+ phosphor with super-long persistent luminescence for over 100 h

X. Shan, X. Lv, D. Chen, Y. Zhang, L. Ning and Y. Liang, Inorg. Chem. Front., 2024, 11, 8314 DOI: 10.1039/D4QI02407A

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