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Highly Sensitive Dual-Mode Optical Thermometry in Double-Perovskite Oxides via Pr<sup>3+</sup>/Dy<sup>3+</sup> Energy Transfer

Hang Zhang, Yujun Liang, Hang Yang, Shiqi Liu, Haoran Li, Yuming Gong, Yongjun Chen, Guogang Li

2020Inorganic Chemistry106 citationsDOI

Abstract

As increasing demand for noncontact temperature sensing, the development of a high-performance optical thermometer probe is more and more urgent. In this work, an efficient dual-mode optical thermometry strategy based on the Pr3+/Dy3+ energy transfer (ET) in some typical double-perovskite oxides is presented, which offers a promising way to design FIR/lifetime dual-mode optical thermometry with excellent temperature-measuring sensitivity and signal discrimination. According to this strategy, double-perovskite La2MgTiO6:Pr3+/Dy3+ phosphors are successfully synthesized. On the basis of diverse thermal responses between Pr3+ and Dy3+, the FIR of Pr3+ to Dy3+ (four FIR mode) in this material displays outstanding optical thermometry performance from 298 to 548 K. The maximum absolute and relative sensitivities (Sa and Sr) of mode 1 are 0.09 and 2.357% K–1, being better than the current optical temperature measurement materials. For the fluorescence lifetime mode, the Sa-max and Sr-max values reach 2.85 × s 10–4 and 1.814% K–1. Furthermore, the dual-mode optical thermometry mechanism was presented and studied. It also demonstrated excellent optical thermometry performance in the other Pr3+/Dy3+ codoped double-perovskite oxides, such as LaMg0.598Nb0.402O3, NaLa(MoO4)2, NaGd(MoO4)2, and NaLa(WO4)2, proving the universality of the presented strategy. This article presents an effective Pr3+/Dy3+ ET pathway for developing new and highly sensitive FIR/lifetime dual-mode optical temperature sensing materials.

Topics & Concepts

ThermometerChemistryDual modePhosphorOptoelectronicsPerovskite (structure)Energy transferAnalytical Chemistry (journal)OpticsMaterials sciencePhysicsElectronic engineeringChromatographyCrystallographyMolecular physicsEngineeringQuantum mechanicsLuminescence Properties of Advanced MaterialsOptical properties and cooling technologies in crystalline materialsSolid State Laser Technologies