Coordinated Solvent Molecules Enable the Excellent Capabilities of Two Zn2+‐Based Complexes in Detecting l‐Arginine via Long‐Lived Luminescence Recovery

Luminescence metal–organic materials (MOMs) are widely used as probes for detection. However, most of such probes are based on fluorescence and work in either turn‐off or turn‐on mode. In contrast, long‐lived (>10 ms) probes (LLPs) with recovery response to analyte are quite rare. Herein “solvati...

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Published inAdvanced functional materials Vol. 34; no. 40
Main Authors Wang, Hui‐Yu, Miao, Lei, Zhang, Bo‐Lun, Sun, Ying‐Ji, Chen, Jun, Liu, Shuqin, Zhang, Wen‐Qi, Wang, Ting, Zhang, Jian‐Jun
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.10.2024
Subjects
afterglow
Afterglows
Arousal
coordinated solvent
crystalline‐to‐crystalline
Fluorescence
Fumigation
Luminescence
Materials recovery
multi‐stimulus‐responsive
Organic materials
Phosphorescence
recovery detection
Room temperature
Solvation
Solvents
Stimuli
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Summary:Luminescence metal–organic materials (MOMs) are widely used as probes for detection. However, most of such probes are based on fluorescence and work in either turn‐off or turn‐on mode. In contrast, long‐lived (>10 ms) probes (LLPs) with recovery response to analyte are quite rare. Herein “solvation complex” strategy is used to prepare two new afterglow complexes with multiple coordinated solvents, trans‐complex 1 with both delayed fluorescence (DF) and room temperature phosphorescence (RTP), and cis‐complex 2 with RTP. Remarkably, they can serve as selective and recovery LLPs for l‐Arginine detection, with limit of detection down to 1.0 × 10−7 M. In addition, heating/fumigation can induce reversible arousal/silence of their afterglow, while H2O/DMSO vapor fumigation causes reversible crystalline‐to‐crystalline transformation between them. Detailed mechanism studies reveal that the change in coordinated solvent, including loss/acquisition, exchange, or replacement, plays a key role in such afterglow multi‐stimuli‐responsive properties. This work not only shows the potential of such long‐lived luminescence complex for recovery detection, but also reveals the unique advantages of solvation complex in the preparation of afterglow multi‐stimuli‐responsive materials Present here are two Zn2+‐based afterglow complexes that can be used as l‐Arginine probes via long‐lived luminescence recovery with limit of detection down to 1.0 × 10‐7 M. In addition, heating/fumigation can cause reversible arousal/silence of their afterglow, while H2O/DMSO vapor fumigation can induce their reversible interconversion via the loss/acquisition, and exchange of coordinated solvent molecules, respectively.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202403734