Graphene oxide-assisted synthesis of N, S Co-doped carbon quantum dots for fluorescence detection of multiple heavy metal ions

Graphene oxide-assisted synthesis of N, S Co-doped carbon quantum dots for fluorescence detection of multiple heavy metal ions

Detection of heavy metal ions (HMIs) in water is an important topic in the field of analytical chemistry and environmental science. Fluorescence spectroscopy is one of the most promising strategies due to its simple instrument, low investment, rapid and convenient operation. However, current fluores...

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Bibliographic Details
Published in:Talanta (Oxford) Vol. 241; p. 123224
Main Authors: Shen, Yujie, Rong, Mingcong, Qu, Xiaodan, Zhao, Bolin, Zou, Jinhui, Liu, Zhenbang, Bao, Yu, He, Ying, Li, Siyi, Wang, Xiaojin, Chen, Meiyun, Chen, Kaiying, Zhang, Yuwei, Niu, Li
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 01-05-2022
Subjects:
Carbon - chemistry
Carbon dots
Fluorescence probe
Graphite
Humans
Ions
Metals, Heavy
Multiple heavy metal ions
Nitrogen - chemistry
Quantum Dots
Spectrometry, Fluorescence - methods
Multiple heavy metal ions
Fluorescence probe
Carbon dots
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Summary:Detection of heavy metal ions (HMIs) in water is an important topic in the field of analytical chemistry and environmental science. Fluorescence spectroscopy is one of the most promising strategies due to its simple instrument, low investment, rapid and convenient operation. However, current fluorescence probes for detecting HMIs are typically selective for certain ions. Herein we reported the development of a novel strategy that determined the total content of HMIs in water by fluorescence spectroscopy. A novel fluorescent nitrogen, sulfur co-doped carbon quantum dots (N, S-CQDs) was prepared via graphene oxide-assisted synthesis method. The results showed that, with the fluorescence quenching strategy, N, S-CQDs exhibited a wide linear response to a series of water-soluble metal ions. The fluorescence of N, S-CQDs is stable in a wide range of pH 4–11. The detection mechanism was proved that the integration, caused by coordination interaction between S element in N, S-CQDs and the d-orbital of associated metal ions, was the main reason for fluorescence quenching. In practice, the N, S-CQDs were applied to determine total content of HMIs in water successfully. Interestingly, further experiment proved that the N, S-CQDs could effectively remove HMIs in water after centrifuging and filtering thoroughly. It was shown that the fluorescence of N, S-CQDs was obviously quenched by the multiple-ions-involved water and scavenging effect of N, S-CQDs on HMIs with centrifugal in which the concentration of individuals meets the Chinese National Standard. This indicates that the N, S-CQDs are of a wide application prospect in water quality analysis. [Display omitted] •A carbon-based fluorescent probe for multi-heavy metal ions was developed by a graphene oxide-assisted synthesis method.•In addition to detecting metal ions, the fluorescent probe provides a simple and pollution-free heavy metal recovery method.•The coordination between S element (N, S-CQDs) and the d orbitals (metal ions) is the main reason fluorescence quenching.
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content type line 23
ISSN:0039-9140
1873-3573
DOI:10.1016/j.talanta.2022.123224