AI Article Synopsis
- Ultrasmall fluorescent nanomaterials are promising as probes but often suffer from issues like structural damage and low sensitivity.
- The study introduces star-like polymer unimolecular micelles that encapsulate carbon quantum dots and gold nanoclusters to create stable dual-emission ratiometric fluorescence assemblies.
- These assemblies are highly stable, easy to produce, and can quickly and accurately detect copper and glutathione, showcasing their potential for real-time monitoring and information encryption.
Article Abstract
Ultrasmall fluorescent nanomaterials have been widely studied as novel fluorescent probes; however, these nanomaterials are prone to structural damage or aggregation, and the sensitivity and accuracy of most single emission fluorescence probes were very low. Therefore, the controlled synthesis of stable dual-emission ratiometric fluorescence ultrasmall assembly probes still remains a challenge. Herein, star-like polymer unimolecular micelles were utilized as a scaffold template to encapsulate fluorescent ultrasmall carbon quantum dots (CQDs) and gold nanoclusters (AuNCs) via the polymer template directed self-assembly strategy to obtain multiple-responsive ratiometric fluorescent assemblies. The assemblies were ultrastable, well-defined, and nearly monodispersed with controlled size, regular morphology, and pH- and thermal-responsiveness. The assemblies can be applied to realize rapid, sensitive, quantitative, and specific detection of Cu and GSH. Moreover, the convenient rapid real-time detection was realized via the combination of the visualized paper-based sensor, and the multilevel information encryption was also achieved.
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| http://dx.doi.org/10.1021/acs.jpclett.4c00577 | DOI Listing |
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