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Barrierless Exciton Self‐Trapping and Emission Mechanism in Low‐Dimensional Copper Halides

Zengshan Xing, Zhicong Zhou, Guohua Zhong, Christopher C. S. Chan, Yanyan Li, Xinhui Zou, Jonathan E. Halpert, Haibin Su, Kam Sing Wong

2022Advanced Functional Materials69 citationsDOI

Abstract

Abstract Low‐dimensional copper halides having nontoxic elements are attracting increasing attention for their peculiar emission properties. Self‐trapped excitons (STEs) account for their high photoluminescence quantum yields (PLQYs) with emission that can stretch across the entire visible spectrum. However, intrinsic factors that influence the formation or loss of the emissive species in low‐dimensional copper halides remain elusive. Here, a comprehensive study on the STE formation dynamics of one‐dimensional CsCu 2 I 3 and zero‐dimensional Cs 3 Cu 2 I 5 is presented. It is found from STE kinetic analysis that a slower STE formation demonstrated by the 1D structure is not hindered by a potential barrier, but instead related to the number of phonons released in the self‐trapping process. It is further revealed that in 1D CsCu 2 I 3 , the non‐radiative recombination of STEs mainly occurs via the intersection between the STE state and the ground state in the configuration coordinate diagram, placing an intrinsic limit on the PLQY at room temperature. These findings show that the STE formation is affected by both the self‐trapping depth and the phonon energy as opposed to a potential barrier in low‐dimensional copper halides. The better understanding of STE formation and recombination processes provide basis for improving design and performance for broadband light emitting devices.

Topics & Concepts

ExcitonHalidePhotoluminescenceMaterials scienceTrappingCopperChemical physicsSpontaneous emissionPhononRadiative transferGround stateMolecular physicsAtomic physicsCondensed matter physicsPhysicsOptoelectronicsOpticsChemistryInorganic chemistryLaserMetallurgyEcologyBiologyPerovskite Materials and ApplicationsQuantum Dots Synthesis And PropertiesChalcogenide Semiconductor Thin Films
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