Structural Features of Electrodeposited Copper Electrodes for CO2 Conversion

A. S. Reis Machado; T. R. C. Fernandes; Tiago Pardal; Carmen M. Rangel

doi:10.4028/www.scientific.net/MSF.730-732.239

Paper Titles

Influence of Substrate Temperature and Post-Annealing Treatment on the Microstructure and Electric Properties of ZnO:Al Thin Films Deposited by Sputtering
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Localized Electrografting of Diazonium Salts in the SECM Environment
p.221

Morphology Control of Thin P3HT-Si-NCs Composite Films for Hybrid Photovoltaic Cells
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Production and Characterization of Composite Material Useful as a Protective Barrier in Electronic Applications
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Structural Features of Electrodeposited Copper Electrodes for CO₂ Conversion
p.239

Tetraethylortossilicate Plasma Thin Film with Hydrophilic and Hydrophobic Characteristics: Use on Passive Mixers
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Vanadium Oxide Thin Films Synthesized by Reactive Ion Beam Sputter Deposition: Influence of Processing Parameters
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Wettability and Nanotribological Response of Silicon Surfaces Functionalized by Ion Implantation
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Assessment of Materials for Fuselage Panels Considering Fatigue Behavior
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Structural Features of Electrodeposited Copper Electrodes for CO₂ Conversion

Abstract:

Direct electrochemical reduction of CO₂ is a process that could contribute to the reduction of the emission of greenhouse gases by using CO₂ as a raw material for fuel production. This paper focuses on voltammetric studies of functionalized electrodes for the electrochemical conversion of CO₂and reports on its use as a tool for electrode screening and optimization. Nickel substrates modified with copper and ruthenium/copper electrodeposits were studied. Voltammetric experiments indicate that CO₂ electroreduction follows a nickel type mechanism in which this electrochemical reaction occurs simultaneously and in competition with hydrogen evolution. A significant inhibition of hydrogen evolution reaction is observed in nickel modified electrodes. Inhibition characteristics and the onset of carbon dioxide conversion are dependent of the type of electrode functionalization. Voltammetry is thus a powerful tool to evaluate electrode modifications and for tuning electrodes for an optimized electrocatalytic performance.