Insights into the synergistic effect between nickel and molybdenum for catalyzing urea electrooxidation

Wang, Jiaqi; Mo, Funian; Fei, Jinbo; Ling, Wei; Cui, Mangwei; Lei, Hao; Jiang, Li; Huang, Yan

doi:10.1002/cnl2.27

Cited by 8 publications

(2 citation statements)

References 71 publications

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“…The interplanar distances of 0.24 and 0.34 nm are consistent with the lattice of Ni(OH) 2 and match well with the (422) and (131) planes. 22 The element mapping demonstrates that Ni, O, C, and O were all evenly distributed throughout the nanosheets (Fig. 1d-h).…”

Section: Resultsmentioning

confidence: 92%

Facile electrolysis-solvothermal synthesis of NiO_x/graphene for enhanced ethanol oxidation to acetate

Zhao,

Yang,

et al. 2024

Dalton Trans.

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Section: Resultsmentioning

confidence: 92%

Facile electrolysis-solvothermal synthesis of NiO_x/graphene for enhanced ethanol oxidation to acetate

Zhao,

Yang,

et al. 2024

Dalton Trans.

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“…The addition of nickel and other metals into nickel hydroxide has been shown to increase the electrode activity by altering the electronic structure and by expanding the electrochemically active surface area. [39][40][41][42][43][44][45][46][47][48] The inclusion of chromium oxide into nickel has been shown to depress the density of states at the Fermi level of the d-band of nickel, thereby weakening the Ni-O urea bond and decreasing the energy for adsorption. 49 The inclusion of Mo into the nickel hydroxide films causes Ni to complete the Ni(OH) 2 /NiOOH transition at lower onset potentials.…”

Section: Introductionmentioning

confidence: 99%

Catalytic Urea Electrooxidation on Nickel-Metal Hydroxide Foams For Use in A Simplified Dialysis Device

Pyka,

Bergsman,

Stuve

2024

Preprint

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Electrocatalytic urea removal is a promising technology for artificial kidney dialysis and wastewater treatment. Urea electrooxidation was studied on a variety of nickel electrocatalysts modified with Cr, Mo, Mn, and Fe with varying electrochemically active surface and roughness. Mass transfer limits were observed for urea oxidation at physiological concentrations (10 mM). Urea oxidation kinetics were explored at higher concentrations (200 mM), showing improved performance during polarization, but lower currents per active site. A simplified dialysis model was developed to examine the relationship of mass transfer coefficients and extent of reaction on flowrate, composition, and pH of the reacting stream. For a nickel hydroxide catalyst, the model shows that a minimum electrode area of 1314 cm is needed for continuous operation. This research combines experimental data and a computational dialysis model for a simplified continuous dialysis system, highlighting the potential of these catalysts and paving the way for future improvements.

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Catalytic urea electrooxidation on nickel‐metal hydroxide foams for use in a simplified dialysis device

Pyka,

Bergsman,

Stuve

2024

AIChE Journal

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Electrocatalytic urea removal is a promising technology for artificial kidney dialysis and wastewater treatment. Urea electrooxidation was studied on nickel electrocatalysts modified with Cr, Mo, Mn, and Fe. Mass transfer limits were observed for urea oxidation at physiological concentrations (10 mmol L). Urea oxidation kinetics were explored at higher concentrations (200 mmol L), showing improved performance, but with lower currents per active site. A simplified dialysis model was developed to examine the relationship of mass transfer coefficients and extent of reaction on flowrate, composition, and pH of the reacting stream. For a nickel hydroxide catalyst operating at 1.45 V, 37 , and pH 7.1, the model shows a minimum geometric electrode area of 1314 cm2 is needed to remove 3.75 g urea h with a flow rate of 200 mL min for continuous operation.

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Insights into the synergistic effect between nickel and molybdenum for catalyzing urea electrooxidation

Cited by 8 publications

References 71 publications

Facile electrolysis-solvothermal synthesis of NiO_x/graphene for enhanced ethanol oxidation to acetate

Facile electrolysis-solvothermal synthesis of NiO_x/graphene for enhanced ethanol oxidation to acetate

Catalytic Urea Electrooxidation on Nickel-Metal Hydroxide Foams For Use in A Simplified Dialysis Device

Catalytic urea electrooxidation on nickel‐metal hydroxide foams for use in a simplified dialysis device

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Insights into the synergistic effect between nickel and molybdenum for catalyzing urea electrooxidation

Cited by 8 publications

References 71 publications

Facile electrolysis-solvothermal synthesis of NiOx/graphene for enhanced ethanol oxidation to acetate

Facile electrolysis-solvothermal synthesis of NiOx/graphene for enhanced ethanol oxidation to acetate

Catalytic Urea Electrooxidation on Nickel-Metal Hydroxide Foams For Use in A Simplified Dialysis Device

Catalytic urea electrooxidation on nickel‐metal hydroxide foams for use in a simplified dialysis device

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Product

Resources

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Facile electrolysis-solvothermal synthesis of NiO_x/graphene for enhanced ethanol oxidation to acetate

Facile electrolysis-solvothermal synthesis of NiO_x/graphene for enhanced ethanol oxidation to acetate