Mechanoluminescence and Mechanical Quenching of Afterglow Luminescent Particles for Wearable Photonic Display

Optical properties of afterglow luminescent particles (ALPs) in mechanoluminescence (ML) and mechanical quenching (MQ) have attracted great attention for diverse technological applications. However, these unique phenomena need to be more clearly explained for the specific photonic application. Here,...

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Bibliographic Details
Published in:Advanced functional materials 2024-06, Vol.34 (23), p.n/a
Main Authors: Kim, Seong‐Jong, Yang, Fan, Jung, Ho Sang, Hong, Guosong, Hahn, Sei Kwang
Format: Article
Language:English
Subjects:
afterglow luminescence
Afterglows
Biomedical materials
Display devices
Handwriting
Light irradiation
mechanical quenching
Mechanoluminescence
Optical properties
photonic display
Photonics
Quenching
Ultraviolet radiation
Underwater
Wearable technology
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Summary:Optical properties of afterglow luminescent particles (ALPs) in mechanoluminescence (ML) and mechanical quenching (MQ) have attracted great attention for diverse technological applications. However, these unique phenomena need to be more clearly explained for the specific photonic application. Here, ALPs are designed for the development of a wearable and rewritable photonic display system as a communication toolbox under dark conditions or underwater environments with limited communication. This display system demonstrates long‐lasting MQ after short ML along the handwritten trajectories with mechanical pressure and the written content can be easily erased by short UV light irradiation, preserving the system integrity with the high reproducibility of ML and MQ responses. The effect of trapped electrons and the recharging process on the ML and MQ is assessed, which provides insights into their underlying mechanisms. In addition, this display system exhibits remarkable resistance to humidity and retains its rewritable and photonic capabilities underwater for a long‐term period. Furthermore, the rewritable property of display system on human skin is demonstrated, confirming their effectiveness as a wearable photonic display system. Taken together, this research will pave a big new avenue to develop biophotonic materials for various biomedical applications with mechano‐optical conversions. Afterglow luminescent particles for the development of a wearable and rewritable photonic display system as a communication toolbox under dark conditions or underwater environments with limited communication is designed. This display system demonstrates long‐lasting mechanical quenching (MQ) after short mechanoluminescence (ML) along the handwritten trajectories with mechanical pressure, and the written content can be easily by short UV irradiation.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202314861