Redox Reactions in a Layer of Adsorbed Mn(II) Cations and RuO4 Molecules. Synthesis of Manganese Oxide Doped with Ruthenium by Successive Ionic Layer Deposition

Redox Reactions in a Layer of Adsorbed Mn(II) Cations and RuO4 Molecules. Synthesis of Manganese Oxide Doped with Ruthenium by Successive Ionic Layer Deposition

Сonditions were considered for the synthesis of the Ru x MnO y ∙ n H 2 O nanocomposite layers by the ionic deposition method based on successive repeated redox reactions on the substrate surface in a layer of adsorbed Mn(II) cations and RuO 4 molecules. It was found that, under the chosen synthesis...

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Veröffentlicht in:Russian journal of general chemistry 2022-11, Vol.92 (11), p.2339-2345
Hauptverfasser: Kaneva, M. V., Tolstoy, V. P.
Format: Artikel
Sprache:eng
Schlagworte:
Cations
Chemical reactions
Chemical synthesis
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Crystal structure
Deposition
Manganese dioxide
Metal foams
Nanocomposites
Nickel
Reagents
Redox reactions
Ruthenium
Ruthenium oxide
Substrates
Triclinic crystals
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Zusammenfassung:Сonditions were considered for the synthesis of the Ru x MnO y ∙ n H 2 O nanocomposite layers by the ionic deposition method based on successive repeated redox reactions on the substrate surface in a layer of adsorbed Mn(II) cations and RuO 4 molecules. It was found that, under the chosen synthesis conditions, on the nickel surface ruthenium-doped manganese(IV) oxide layers are formed, which have a triclinic crystal structure and consist of a set of nanosheets about 5 nm thick and 20–50 nm in lateral dimensions. Based on the experimental data obtained, the features of chemical reactions occurring on the substrate surface during treatment with each of the reagents were considered. The supercapacitor electrodes obtained using these layers and nickel foam are characterized by a capacitance of 687 F/g in 1 M Na 2 SO 4 solution at a charge-discharge current of 1 A/g.
ISSN:1070-3632
1608-3350
DOI:10.1134/S1070363222110184