Optical and quantitative detection of cobalt ion using graphitic carbon nitride-based chemosensor for hydrometallurgy of waste lithium-ion batteries

A hydrometallurgy is one of the most important techniques for recycling waste LIBs, where identifying the exact composition of the metal-leached solution is critical in controlling the metal extraction efficiency and the stoichiometry of the regenerated product. In this study, we report a simple and...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2023-02, Vol.315, p.137789-137789, Article 137789
Main Authors: An, Byeong-Hyeon, Lee, Tae-Gyu, Khan, Tamal Tahsin, Seo, Hye-Won, Hwang, Hyun Jin, Jun, Young-Si
Format: Article
Language:English
Subjects:
Carbon nitride
Cobalt - chemistry
Cobalt ion
Coloring Agents
Electric Power Supplies
Graphite
Ions
Lithium
Metals
Optical sensing
Photoluminescence
Recycling - methods
Waste battery recycling
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Summary:A hydrometallurgy is one of the most important techniques for recycling waste LIBs, where identifying the exact composition of the metal-leached solution is critical in controlling the metal extraction efficiency and the stoichiometry of the regenerated product. In this study, we report a simple and selective optical detection of high-concentrated Co2+ using a graphitic carbon nitride (g–CN)–based fluorescent chemosensor. g-CN is prepared by molten salt synthesis using dicyandiamide (DCDA) and LiI/KI. The mass ratio of LiI/KI to DCDA modifies the resulting g-CN (CNI) in terms of in-plane molecular distances of base sites including cyano functional groups (─CN) and fluorescent emission wavelength via nucleophilic substitution. The fluorescent sensing performance of CNIs is evaluated through photoluminescence (PL) emission spectroscopy in a broad Co2+ concentration range (10−4–100 M). The correlation between the surface exposure of hidden nitrogen pots (base sites) and PL intensity change is achieved where the linear relationship between the PL quenching and the logarithm of Co2+ concentration in the analyte solution is well established with the regression of 0.9959. This study will provide the design principle of the chemosensor suitable for the fast and accurate optical detection of Co2+ present in a broad concentration range for hydrometallurgy for the recycling of waste LIBs. [Display omitted] •Heterogeneous fluorescent chemosensors are prepared by simple molten salt synthesis for hydrometallurgy of waste LIBs.•Stoichiometric utilization of LiI/KI enables to prepare the graphitic carbon nitride-based all-in-one chemosensor (CNI).•CNI-based chemosensors achieve a selective optical sensing of Co2+ in the wide concentration range of 10−5–10−1 M.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2023.137789