4.6 Article

Tunable luminescence in Eu3+/Sm3+ single-doped LuNbO4 for optical thermometry and anti-counterfeiting

Journal

JOURNAL OF MATERIALS CHEMISTRY C
Volume 11, Issue 29, Pages 9974-9983

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d3tc01780j

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Rare-earth (RE) ion-doped luminescent materials have been widely used in scientific research and practical applications. Designing a single matrix with dual-emitting centers and color-tunable properties has become a trend in the development of luminescent materials. In this study, Eu3+/Sm3+ single-doped LuNbO4 (LNO) phosphors were developed, demonstrating multi-color emissions and anti-thermal quenching behavior due to energy transfer from the host to activators. Furthermore, these phosphors showed high temperature sensitivity and adjustable emissions, making them potential candidates for anti-counterfeiting and other applications.
Rare-earth (RE) ion-doped luminescent materials have been widely utilized in both scientific research and practical applications. Recently, designing a single matrix with dual-emitting centers and color-tunable properties to expand their applications has become a trend in the development of luminescent materials. Here, a series of Eu3+/Sm3+ single-doped LuNbO4 (LNO) phosphors, with characteristic emissions of the host and Eu3+/Sm3+ activators, are developed. Interestingly, owing to the energy transfer (ET) from the host to activators, the designed phosphors exhibit multi-color emissions and anti-thermal quenching behavior. Based on the different responses of the matrix and Eu3+/Sm3+ ions to temperature, the maximum relative sensitivity (S-r) values of LNO:0.001Eu(3+) and LNO:0.005Sm(3+) samples reach as high as 2.45% K-1 (@350 K) and 2.49% K-1 (@362 K), respectively. Moreover, under 261/365 nm light excitation, discriminable colors and emission-adjustable properties of the phosphors and LNO:0.005Eu(3+)/Sm3+ -polydimethylsiloxane (PDMS) films from 303 to 453 K can be realized, demonstrating their huge potential in anti-counterfeiting. The developed LNO:Eu3+/Sm3+ samples present highly temperature-sensitive characteristics and excellent optical performance, and also show potential for application in luminescence thermometry, information security, anti-counterfeiting and LEDs.

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