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Design of anti-thermal quenching Pr<sup>3+</sup>-doped niobate phosphors based on a charge transfer and intervalence charge transfer band excitation-driven strategy

Chunwei Yang, Ning Guo, Song Qu, Qincan Ma, Jianxia Liu, Shunyi Chen, Ruizhuo Ouyang

2023Inorganic Chemistry Frontiers19 citationsDOI

Abstract

Based on the charge transfer and intervalence charge transfer mechanism, an excitation-driven strategy was employed to achieve single compensation and dual compensation anti-thermal quenching of 1 D 2 red-emitting in YNbO 4 :Pr 3+ phosphor.

Topics & Concepts

PhosphorExcitationCharge (physics)Quenching (fluorescence)DopingThermalMaterials scienceCompensation (psychology)Thermal transferLuminescenceAtomic physicsChemistryOptoelectronicsFluorescenceOpticsPhysicsNanotechnologyThermodynamicsQuantum mechanicsPsychoanalysisPsychologyLayer (electronics)Luminescence Properties of Advanced MaterialsPhotorefractive and Nonlinear OpticsPerovskite Materials and Applications
Design of anti-thermal quenching Pr<sup>3+</sup>-doped niobate phosphors based on a charge transfer and intervalence charge transfer band excitation-driven strategy | Litcius