Preparation and Characterization of Carbazole-Based Luminogen with Efficient Emission in Solid and Solution States

Organic luminescent materials with high luminescence efficiency in both solution and solid states, namely dual-state emission (DSE), have attracted considerable attention due to their promising applications in various fields. In order to enrich the variety of DSE materials, carbazole, similar to tri...

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Published inMaterials Vol. 16; no. 11; p. 4193
Main Authors Zhang, Beibei, Wei, Lingzhong, Tang, Xuansi, Jiang, Zizhan, Guo, Song, Zou, Linmin, Xie, Huihong, Gong, Yongyang, Liu, Yuanli
Format Journal Article
LanguageEnglish
Published Switzerland MDPI AG 05.06.2023
MDPI
Subjects
carbazole
Carbazoles
dual state emission
Efficiency
Emission
Excitation
Ground state
Hazardous materials
high efficiency
Hydrocarbons
Luminescence quenching
Mathematical analysis
Mechanoluminescence
Molecular conformation
Optical properties
organic luminogens
Single crystals
high efficiency
organic luminogens
carbazole
dual state emission
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Summary:Organic luminescent materials with high luminescence efficiency in both solution and solid states, namely dual-state emission (DSE), have attracted considerable attention due to their promising applications in various fields. In order to enrich the variety of DSE materials, carbazole, similar to triphenylamine (TPA), was utilized to construct a novel DSE luminogen named 2-(4-(9H-carbazol-9-yl)phenyl)benzo[d]thiazole (CZ-BT). CZ-BT exhibited DSE characteristics with fluorescence quantum yields of 70, 38 and 75% in solution, amorphous and crystalline states, respectively. CZ-BT shows thermochromic and mechanochromic properties in solution and solids, respectively. Theoretical calculations show that there is a small conformational difference between the ground state and the lowest singly excited state of CZ-BT and that it exhibits a low non-radiative transition characteristic. The oscillator strength during the transition from the single excited state to the ground state reaches 1.0442. CZ-BT adopts a distorted molecular conformation with intramolecular hindrance effects. The excellent DSE properties of CZ-BT can be explained well using theoretical calculations and experimental results. In terms of application, the CZ-BT has a detection limit for the hazardous substance picric acid of 2.81 × 10 mol/L.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma16114193