Luminescence intensity ratio (LIR) thermometers have aroused great interest in recent research due to their high spatial resolution, superior precision and fast response, which can avoid the defects of traditional contact sensors including low spatial, thermal and temporal resolution. In addition, LIR thermometers enable non-invasive measurements in vivo without physical contact between the observers and target analytes. However, the current LIR thermometers focus on the visible range (400–650 nm), which suffer from limited penetration depth in biological tissues. Herein, a multimode LIR thermometer covering all near-infrared (NIR) transparency windows is designed based on Y
3Al
5O
12: Cr
3+/Ln
3+ (Ln=Ho, Er, Yb) phosphors under 980 nm excitation. The Cr
3+/Ln
3+-activated up-conversion emissions provide a proportional luminescence thermometer in NIR-I mode by virtue of the energy transfer between Cr
3+ ions and Ln
3+ ions. The downshifting emissions of Er
3+/Ho
3+ are applied to the LIR thermometry in NIR-III/II mode. Under the influence of the crystal field, the emission spectrum of
4H
13/2→
4I
15/2 transition splits into four peaks in NIR-III window, which allows the thermal coupling thermometry of Mode-III. Three modes show distinct thermometric performance in different NIR transparency windows and temperature ranges, and each window contributing to detect deep-tissue temperature in a unique way.
Important Date
-
Conference Date
-
Sep 15
2024
Draft paper submission deadline
-
Sep 15
2024
Sponsored By
ShenZhen University
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