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Fluorescence-based monitoring of the pressure-induced aggregation microenvironment evolution for an AIEgen under multiple excitation channels

Shuang Tong, Jianhong Dai, Jiangman Sun, Yuan Yuan Liu, Xiaoli Ma, Zhehong Liu, Teng Ma, Jiao Tan, Zhen Yao, Shanmin Wang, Haiyan Zheng, Kai Wang, Fang Hong, Xiaohui Yu, Chunxiao Gao, Xinggui Gu

2022Nature Communications49 citationsDOIOpen Access PDF

Abstract

The development of organic solid-state luminescent materials, especially those sensitive to aggregation microenvironment, is critical for their applications in devices such as pressure-sensitive elements, sensors, and photoelectric devices. However, it still faces certain challenges and a deep understanding of the corresponding internal mechanisms is required. Here, we put forward an unconventional strategy to explore the pressure-induced evolution of the aggregation microenvironment, involving changes in molecular conformation, stacking mode, and intermolecular interaction, by monitoring the emission under multiple excitation channels based on a luminogen with aggregation-induced emission characteristics of di(p-methoxylphenyl)dibenzofulvene. Under three excitation wavelengths, the distinct emission behaviors have been interestingly observed to reveal the pressure-induced structural evolution, well consistent with the results from ultraviolet-visible absorption, high-pressure angle-dispersive X-ray diffraction, and infrared studies, which have rarely been reported before. This finding provides important insights into the design of organic solid luminescent materials and greatly promotes the development of stimulus-responsive luminescent materials.

Topics & Concepts

LuminescenceStackingFluorescenceMaterials scienceExcitationOptoelectronicsIntermolecular forceInfraredAbsorption (acoustics)NanotechnologyChemical physicsChemistryOpticsMoleculePhysicsQuantum mechanicsOrganic chemistryComposite materialLuminescence and Fluorescent MaterialsPerovskite Materials and ApplicationsOrganic Light-Emitting Diodes Research
Fluorescence-based monitoring of the pressure-induced aggregation microenvironment evolution for an AIEgen under multiple excitation channels | Litcius