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Microwave-assisted synthesis of biomass-derived N-doped carbon dots for metal ion sensing

Mehedi Hasan, Balachandran Baheerathan, Shrikanta Sutradhar, Ronak Shahbandinejad, Sudip Kumar Rakshit, Janusz A. Koziński, Dongbing Li, Yulin Hu, Kang Kang

2025Carbon Research21 citationsDOIOpen Access PDF

Abstract

Abstract Biomass-derived carbon dots (CDs) have gained significant research interest for environmental monitoring applications thanks to their cost-effectiveness and sustainability. Using eco-friendly biowastes as precursors for CDs production offers an alternative to expensive and unsustainable inorganic and chemically synthesized CDs. This study presents the findings regarding the successful synthesis of biomass-based nitrogen-doped carbon dots (N-CDs) via a rapid, cost-effective, and environmentally friendly microwave-assisted method. Carboxymethyl cellulose (CMC) and glycine were used as carbon precursors and nitrogen dopants for the first time. The N-CDs exhibited a moderately high quantum yield of 31.6 ± 1.5% with an optimal fluorescence excitation wavelength of 400 nm. FTIR, CHNS, and SEM–EDX analyses characterized the N-CDs' surface functional groups and elemental composition. The optical stability of the N-CDs was validated across varying pH levels and NaCl concentrations. The N-CDs displayed notable selectivity and sensitivity for Fe 3 ⁺, Cu 2 ⁺, and Hg 2 ⁺ ions. The primary quenching mechanisms involve electrostatic interactions, π–π interactions, inner filter effects, and energy transfer. Stern–Volmer analysis revealed strong linear quenching for Fe 3 ⁺, Cu 2 ⁺, and Hg 2 ⁺ ions within the 0–10 µM range concentrations, with detection limits (LOD) of 6.0 µM, 1.41 µM and 1.36 µM for Fe 3 ⁺, Cu 2 ⁺, and Hg 2 ⁺, respectively. The fluorescence quenching for Fe 3 ⁺ ions enhanced sensitivity at higher concentrations, while selectivity decreased at lower concentrations. These findings highlight the potential of these N-CDs as a cost-effective and sustainable tool for environmental monitoring, offering a promising approach to addressing critical water contamination issues. Graphical Abstract

Topics & Concepts

Materials scienceMicrowaveDopingMetalCarbon fibersBiomass (ecology)Metal ions in aqueous solutionIonOptoelectronicsNanotechnologyChemistryMetallurgyComputer scienceTelecommunicationsComposite numberOrganic chemistryComposite materialGeologyOceanographyCarbon and Quantum Dots ApplicationsAdvanced biosensing and bioanalysis techniquesNanocluster Synthesis and Applications
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