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Ultrasensitive Optical Thermometry via Inhibiting the Energy Transfer in Zero-Dimensional Lead-Free Metal Halide Single Crystals

Yanqing Wu, Juntao Li, Daoyuan Zheng, Xusheng Xia, Songqiu Yang, Yang Yang, Tianxin Bai, Xiaochen Wang, Junsheng Chen, Bin Yang

2022The Journal of Physical Chemistry Letters25 citationsDOI

Abstract

Self-referencing optical thermometry based on the fluorescence intensity ratio (FIR) have drawn extensive attention as a result of their high sensitivity and non-invasively fast response to temperature. However, it is a great challenge for luminescent materials to achieve simultaneously high absolute and relative temperature sensitivity based on the FIR technique. Herein, we developed a novel optical thermometer by designing hybrid lead-free metal halide (TTPhP)2MnCl4:Sb3+ (TTPhP+ = tetraphenylphosphonium cation) single crystals with multimodal photoluminescence (PL). The large TTPhP+ organic chain resulted in isolated [MnCl4]2– and [SbCl5]2– in the single crystal, which leads to a negligible energy trasfer process within them. Therefore, the two PL bands (band 1 from [MnCl4]2–) with a peak at 518 nm and band 2 (from [SbCl5]2) with a peak at 640 nm exhibit different thermal-quenching effects, which resulted in excellent temperature sensitivity, with the maximum absolute and relative sensitivities reaching 0.236 K–1 and 3.77% K–1 in a temperature range from 300 to 400 K. Both the absolute and relative sensitivities are among the highest values for luminescence thermometry.

Topics & Concepts

HalideMaterials scienceLead (geology)MetalEnergy transferZero (linguistics)OptoelectronicsChemistryChemical physicsInorganic chemistryMetallurgyLinguisticsGeologyGeomorphologyPhilosophyLuminescence Properties of Advanced MaterialsOptical properties and cooling technologies in crystalline materialsPerovskite Materials and Applications
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