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Activation of self-assembled CaWO4 nanocrystals via Mn-incorporation toward nonenzymatic electrocatalytic glucose oxidation
Nagy, Levente Alex Besic, Hanka Albero, Josep Martínez-Belmonte, Marta Soliman Tamayo, Borja Khatabi Tong, Wenming Farràs, Pau
Nagy, Levente Alex
Besic, Hanka
Albero, Josep
Martínez-Belmonte, Marta
Soliman Tamayo, Borja Khatabi
Tong, Wenming
Farràs, Pau
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Publication Date
2025-12-28
Type
journal article
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Citation
Nagy, Levente Alex, Besic, Hanka, Albero, Josep, Martínez-Belmonte, Marta, Soliman Tamayo, Borja Khatabi, Tong, Wenming, & Farràs, Pau. (2026). Activation of self-assembled CaWO4 nanocrystals via Mn-incorporation toward nonenzymatic electrocatalytic glucose oxidation. ACS Applied Nano Materials, 9(1), 401-412. https://doi.org/10.1021/acsanm.5c04672
Abstract
Integrating foreign metal ions into mixed metal oxide scaffolds, such as CaWO4, by a wet chemistry coprecipitation method is an efficient approach for regulating the chemical composition, which determines the structure and properties and, in turn, offers a versatile platform for enhancements of intrinsic properties and introduction of additional attributes in the host material. In this work, a series of Ca1–xMnxWO4 was prepared via a coprecipitation process at 30 °C to exhibit sphere-like hierarchical structures assembled from individual nanocrystals. The solid solubility limit of Mn in CaWO4 is estimated to be ∼24% for this synthetic approach. The nanocrystals exhibit nonstoichiometric amorphous layers on the surface, which are expected for this type of materials synthesized under such mild conditions. The successful incorporation of Mn into the crystal lattice of CaWO4 led to an isotropic contraction of the crystal unit cells as well as the shifting and merging of several vibrational modes. Cyclic voltammetry confirmed the activity of Ca1–xMnxWO4 for the electrooxidation of glucose, which is directly linked to the presence of Mn in CaWO4. With the highest Mn content, Ca0.759Mn0.241WO4 achieved sensitivities of 3.80 and 1.00 μA·mM–1·cm–2 for glucose concentrations in the ranges of 0.002–0.2 and 0.2–1 mM, respectively, which are 237 and 60 times increases from that of CaWO4. The limit of detection and lower limit of quantitation were estimated to be 14 and 48 μM, respectively, with reasonable reproducibility and repeatability.
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American Chemical Society
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CC BY-NC-ND