Reaction of hydrogen evolution on Co−Mo (W) and Ni−Re electrolytic alloys in alkaline media

Kuznetsov, V. V.; Gamburg, Yu. D.; Zhalnerov, M. V.; Zhulikov, V. V.; Batalov, Roman S.

doi:10.1134/s1023193516090068

Cited by 8 publications

(3 citation statements)

References 25 publications

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“…Одним из возможных применений сплавам вольфрама является использование их в качестве перспективных каталитически-активных слоев для реакции выделения водорода [56], но существует и перспектива их использования в качестве антикоррозионных покрытий [57,58]. Отмечается [57], что введение вольфрама в сплавы никеля приводит к улучшению его антикоррозионных свойств за счет снижения пористости осаждаемого слоя.…”

Section: электрохимическое и химическое осаждение вольфрамсодержащих ...unclassified

Advanced anticorrosive coatings based on tungsten, its alloys and compounds

Dushik,

Shaporenkov,

Shapagina

2023

cpmrm

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В работе обобщены современные представления о вольфраме и его сплавах в контексте их применения в качестве коррозионностойких материалов и антикоррозионных покрытий. Представлены основные свойства систем на основе вольфрама и его сплавов, включая структурные, физико-механические и химические характеристики. Особое внимание уделено вопросам коррозионной стойкости и способам получения материалов и покрытий на основе вольфрама.

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Section: электрохимическое и химическое осаждение вольфрамсодержащих ...unclassified

Advanced anticorrosive coatings based on tungsten, its alloys and compounds

Dushik,

Shaporenkov,

Shapagina

2023

cpmrm

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“…In order to lower the use of these traditional non-renewable fossil fuels, there is an incentive to develop and employ more and more renewable, sustainable and clean energy technologies including solar energy, tides energy, wind energy, hydrogen-fueled, and biomass technologies [4][5][6]. The production of hydrogen based on electrolysis of water can be employed as a potential and energetic alternative due to the fact that hydrogen presents these advantages of being pollution-free, high-energy-density and zero carbon dioxide emissions and the technology can obtain high purity hydrogen [7][8][9][10][11][12][13][14][15][16][17][18][19]. However, at present, preparing hydrogen gas from electrolysis is relatively expensive principally due to the use of noble-metal electrocatalysts [20], thus, in order to minimize hydrogen production cost, it has been quite urgent to develop some cheap and high-performance catalysts with low overpotential, high electronic conductivity, good charge transfer kinetics and long-term stability for hydrogen evolution reaction (HER) and then they can be employed in the practical hydrogen production.…”

Section: Introductionmentioning

confidence: 99%

“…In recent decades, non-noble transition metals catalysts including metal nitrides [16,21], metal sul des [17,22], metal selenides [15,23] and transition-metal alloys [8, [10][11][12]24] had been successfully prepared and exhibited much absorbing consequence. Among these catalysts, Co-Mo alloy and its composite materials are important and promising electrocatalysts for HER due to the fact that these electrode materials exhibit many outstanding properties such as long-term electrochemical stability, good electrical conductivity, high corrosion resistance, outstanding catalytic activity and low overpotential for the HER [8-12, 15, 19].…”

Section: Introductionmentioning

confidence: 99%

Pure pompon structured Co–Mo alloy electro-deposited from ethylene glycol solution and used as electrocatalysts for hydrogen evolution reaction

Guo

et al. 2023

J Appl Electrochem

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Design, development and fabrication of electrode materials with low-cost, excellent inherent electrocatalytic activity and stability are one of the most key challenges in the electrochemical water splitting technique. We employ deposition technique to fabricate the pure pompon structured Co-Mo alloy electrocatalysts from ethylene glycol (EG) solution, in which the pure pompon structure presents highly inherent electrocatalytic activity for hydrogen evolution reaction (HER). The co-deposition behavior of Co(II) and Mo(VI) and Co-Mo electro-crystallization mechanism in ethylene glycol(EG) are recorded using cyclic voltammetry (CV) and chronoamperometry (CA). These results indicate that the Co-Mo codeposition is representative induced deposition; Co(II) species can facilitate Co-Mo co-deposition, inversely, Mo(VI) species can inhibit Co(II) reduction and the effect can be enhanced as Mo(VI) concentration increases. Additionally, Co-Mo co-deposition in EG takes place through an instantaneous nucleation and diffusion-controlled three-dimensional growth mechanism. Co-Mo deposits with various Mo contents and different microstructures can be obtained from the EG solution. SEM micrographs present that the Co-Mo deposits with 1.56 wt.% Mo present a pure pompon microstructure. Bene ting from the composition engineering by alloying with Mo, as well as the simultaneous presence of a suitable pompon structure, Co-Mo deposits with 1.56 wt.% exhibits prominent electrocatalytic durability and activity with a η 10 of 84 mV for HER in a 1.0 M KOH.

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