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Energy Transfer‐Assisted Color Conversion of Persistent Mechanoluminescence in RhB@SiO<sub>2</sub>/SrAl<sub>2</sub>O<sub>4</sub>:Eu,Dy System for Multilevel Information Encryption

Yuan Deng, Danni Peng, Cheng‐Long Shen, Junlu Sun, Guangsong Zheng, Shulong Chang, Ya‐Chuan Liang, Jun He, Chongxin Shan, Lin Dong

2024Laser & Photonics Review31 citationsDOI

Abstract

Abstract Persistent mechanoluminescence (PML) is highly desirable for its ability to overcome transient‐emitting behavior, but its applications are hindered by the limited emission wavelengths. Herein, a universal chemical interlinkage‐assisted efficient energy transfer (ET) strategy is introduced to achieve color conversion from green to red in traditional PML materials. A straightforward chemical route to create the RhB@SiO 2 /SAOED system is established via covalent chemical interlinkage by depositing mesoporous silica‐encapsulated Rhodamine B (RhB) nanoparticles (RhB@SiO 2 ) onto SrAl 2 O 4 :Eu, Dy (SAOED) particles. The resulting system exhibits a high ET efficiency of 53.5%. The multicolor PML of the RhB@SiO 2 /SAOED system remains visible to the naked eye for exceeding 28 s after mechanical stimulation. With this unique PML behavior, the RhB@SiO 2 /SAOED system demonstrates the potential applications ranging from visualized reading activities to multi‐mode anticounterfeiting. This universal PML color‐conversion strategy provides a new approach to high‐performance mechanical light energy‐conversion systems and may further inspire more diverse functional applications of classical PML materials.

Topics & Concepts

MechanoluminescenceMaterials scienceEnergy transferEncryptionOptoelectronicsOpticsPhosphorEngineering physicsComputer sciencePhysicsOperating systemLuminescence and Fluorescent MaterialsLuminescence Properties of Advanced MaterialsRandom lasers and scattering media