Electrochemical reduction of carbon dioxide at low overpotential on a polyaniline/Cu2O nanocomposite based electrode

[Display omitted] •Potentiostatic and current deposition technique was used to fabricate electrodes.•Cu2O dispersed polyaniline electrodes was fabricated.•CO2 was reduced by potential electrolysis method at different potentials.•A faradaic efficiency of 30.4% and 63.0% HCOOH & CH3COOH was observ...

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Veröffentlicht in:	Applied energy 2014-05, Vol.120, p.85-94
Hauptverfasser:	Grace, Andrews Nirmala, Choi, Song Yi, Vinoba, Mari, Bhagiyalakshmi, Margandan, Chu, Dae Hyun, Yoon, Yeoil, Nam, Sung Chan, Jeong, Soon Kwan
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Sprache:	eng
Schlagworte:	Acetic acid Applied sciences CARBON DIOXIDE COPPER OXIDE Cu2O Electrochemical CO2 reduction Electrodes Energy Exact sciences and technology Faradaic efficiency H-Type cell Membrane cell MICA MICROSTRUCTURES Nanostructure OXIDES Polarization Polyaniline Polyanilines POLYMERS Reduction Reduction (electrolytic)
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container_title	Applied energy
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creator	Grace, Andrews Nirmala Choi, Song Yi Vinoba, Mari Bhagiyalakshmi, Margandan Chu, Dae Hyun Yoon, Yeoil Nam, Sung Chan Jeong, Soon Kwan
description	[Display omitted] •Potentiostatic and current deposition technique was used to fabricate electrodes.•Cu2O dispersed polyaniline electrodes was fabricated.•CO2 was reduced by potential electrolysis method at different potentials.•A faradaic efficiency of 30.4% and 63.0% HCOOH & CH3COOH was observed at −0.3V. The electrochemical reduction of CO2 using Cu2O nanoparticle decorated polyaniline matrix (PANI/Cu2O) in 0.1M tetrabutylammonium perchlorate (TBAP) and methanol electrolyte was investigated under ambient conditions. The experiment was carried out in a divided H-type two-compartment cell with a Nafion membrane as diaphragm separating the cathodic and anodic compartments. The catalyst was synthesized electrochemically as a thin film by using cyclic voltammetry and constant current mode deposition technique. The as-fabricated electrode was analyzed with various techniques to probe the nature and composition of the nanoparticles deposited onto the polyaniline matrix, which confirmed the presence of well-defined Cu (I) species in the film. The reduction of CO2 was carried out at various polarization potentials; the main products were formic and acetic acid with faradaic efficiencies of 30.4% and 63.0% at a polarization potential of −0.3V vs. SCE (sat. KCl). A possible reduction pathway is through the formation of Had atoms and subsequent transfer to CO2 through the polymer film to form the products. An appreciable efficiency was achieved in the formation of formic acid and acetic acid with the developed catalyst.
doi_str_mv	10.1016/j.apenergy.2014.01.022
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The electrochemical reduction of CO2 using Cu2O nanoparticle decorated polyaniline matrix (PANI/Cu2O) in 0.1M tetrabutylammonium perchlorate (TBAP) and methanol electrolyte was investigated under ambient conditions. The experiment was carried out in a divided H-type two-compartment cell with a Nafion membrane as diaphragm separating the cathodic and anodic compartments. The catalyst was synthesized electrochemically as a thin film by using cyclic voltammetry and constant current mode deposition technique. The as-fabricated electrode was analyzed with various techniques to probe the nature and composition of the nanoparticles deposited onto the polyaniline matrix, which confirmed the presence of well-defined Cu (I) species in the film. The reduction of CO2 was carried out at various polarization potentials; the main products were formic and acetic acid with faradaic efficiencies of 30.4% and 63.0% at a polarization potential of −0.3V vs. SCE (sat. KCl). 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The electrochemical reduction of CO2 using Cu2O nanoparticle decorated polyaniline matrix (PANI/Cu2O) in 0.1M tetrabutylammonium perchlorate (TBAP) and methanol electrolyte was investigated under ambient conditions. The experiment was carried out in a divided H-type two-compartment cell with a Nafion membrane as diaphragm separating the cathodic and anodic compartments. The catalyst was synthesized electrochemically as a thin film by using cyclic voltammetry and constant current mode deposition technique. The as-fabricated electrode was analyzed with various techniques to probe the nature and composition of the nanoparticles deposited onto the polyaniline matrix, which confirmed the presence of well-defined Cu (I) species in the film. The reduction of CO2 was carried out at various polarization potentials; the main products were formic and acetic acid with faradaic efficiencies of 30.4% and 63.0% at a polarization potential of −0.3V vs. SCE (sat. KCl). A possible reduction pathway is through the formation of Had atoms and subsequent transfer to CO2 through the polymer film to form the products. 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The electrochemical reduction of CO2 using Cu2O nanoparticle decorated polyaniline matrix (PANI/Cu2O) in 0.1M tetrabutylammonium perchlorate (TBAP) and methanol electrolyte was investigated under ambient conditions. The experiment was carried out in a divided H-type two-compartment cell with a Nafion membrane as diaphragm separating the cathodic and anodic compartments. The catalyst was synthesized electrochemically as a thin film by using cyclic voltammetry and constant current mode deposition technique. The as-fabricated electrode was analyzed with various techniques to probe the nature and composition of the nanoparticles deposited onto the polyaniline matrix, which confirmed the presence of well-defined Cu (I) species in the film. The reduction of CO2 was carried out at various polarization potentials; the main products were formic and acetic acid with faradaic efficiencies of 30.4% and 63.0% at a polarization potential of −0.3V vs. SCE (sat. KCl). 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subjects	Acetic acid Applied sciences CARBON DIOXIDE COPPER OXIDE Cu2O Electrochemical CO2 reduction Electrodes Energy Exact sciences and technology Faradaic efficiency H-Type cell Membrane cell MICA MICROSTRUCTURES Nanostructure OXIDES Polarization Polyaniline Polyanilines POLYMERS Reduction Reduction (electrolytic)
title	Electrochemical reduction of carbon dioxide at low overpotential on a polyaniline/Cu2O nanocomposite based electrode
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