Quantification of formaldehyde production during alkaline methanol electrooxidation

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Authors

  • Theresa Haisch
  • Fabian Kubannek
  • Christoph Haisch
  • Detlef W. Bahnemann
  • Ulrike Krewer

Research Organisations

External Research Organisations

  • Technische Universität Braunschweig
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Details

Original languageEnglish
Pages (from-to)57-62
Number of pages6
JournalElectrochemistry communications
Volume102
Early online date23 Mar 2019
Publication statusPublished - May 2019

Abstract

The alkaline methanol electrooxidation reaction (MOR) in alkaline direct methanol fuel cells is still very little understood with regard to its electrochemical behavior. Theoretically, when using a rotating disk (RDE) as working electrode, the limiting current from an electrochemical reaction increases with the rotation rate as described by Levich. Contrary to this principle, the current resulting from the alkaline MOR does not increase, but decreases with rotation rate. In this work, we investigate the reason for this phenomenon using the method described by Nash and modified by Belman to quantify formaldehyde, a reaction intermediate of the alkaline methanol electrooxidation. The amount of formaldehyde is in direct relation to the rotation rate, proving that the current density loss can originate from an intensified removal of formaldehyde into the bulk solution. We analyse the influence of the electrolyte and methanol concentration on the formation of formaldehyde in order to investigate which conditions support the complete oxidation pathway and suppress the incomplete oxidation to formaldehyde. The concentration ratio as well as the absolute concentrations are of great importance for the pathways taking place. A low electrolyte concentration leads to an increase of the formaldehyde but decreasing the methanol concentration results in an absence of formaldehyde in the bulk solution.

Keywords

    Alkaline electrolyte, Chronoamperometric measurement, Formaldehyde, Methanol electrooxidation, Nash method

ASJC Scopus subject areas

Cite this

Quantification of formaldehyde production during alkaline methanol electrooxidation. / Haisch, Theresa; Kubannek, Fabian; Haisch, Christoph et al.
In: Electrochemistry communications, Vol. 102, 05.2019, p. 57-62.

Research output: Contribution to journalArticleResearchpeer review

Haisch T, Kubannek F, Haisch C, Bahnemann DW, Krewer U. Quantification of formaldehyde production during alkaline methanol electrooxidation. Electrochemistry communications. 2019 May;102:57-62. Epub 2019 Mar 23. doi: 10.1016/j.elecom.2019.03.013, 10.15488/9845
Haisch, Theresa ; Kubannek, Fabian ; Haisch, Christoph et al. / Quantification of formaldehyde production during alkaline methanol electrooxidation. In: Electrochemistry communications. 2019 ; Vol. 102. pp. 57-62.
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title = "Quantification of formaldehyde production during alkaline methanol electrooxidation",
abstract = "The alkaline methanol electrooxidation reaction (MOR) in alkaline direct methanol fuel cells is still very little understood with regard to its electrochemical behavior. Theoretically, when using a rotating disk (RDE) as working electrode, the limiting current from an electrochemical reaction increases with the rotation rate as described by Levich. Contrary to this principle, the current resulting from the alkaline MOR does not increase, but decreases with rotation rate. In this work, we investigate the reason for this phenomenon using the method described by Nash and modified by Belman to quantify formaldehyde, a reaction intermediate of the alkaline methanol electrooxidation. The amount of formaldehyde is in direct relation to the rotation rate, proving that the current density loss can originate from an intensified removal of formaldehyde into the bulk solution. We analyse the influence of the electrolyte and methanol concentration on the formation of formaldehyde in order to investigate which conditions support the complete oxidation pathway and suppress the incomplete oxidation to formaldehyde. The concentration ratio as well as the absolute concentrations are of great importance for the pathways taking place. A low electrolyte concentration leads to an increase of the formaldehyde but decreasing the methanol concentration results in an absence of formaldehyde in the bulk solution.",
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author = "Theresa Haisch and Fabian Kubannek and Christoph Haisch and Bahnemann, {Detlef W.} and Ulrike Krewer",
note = "Funding information: The authors gratefully acknowledge financial support from Deutsche Forschungsgemeinschaft (ADMFC/AOBJ: 622591) and Federal Ministry of Education and Research BMBF (Project “DuaSol” No. 03SF0482C). We further acknowledge support by the German Research Foundation and the Open Access Publication Funds of the Technische Universit{\"a}t Braunschweig. The authors gratefully acknowledge financial support from Deutsche Forschungsgemeinschaft (ADMFC/AOBJ: 622591 ) and Federal Ministry of Education and Research BMBF (Project “DuaSol” No. 03SF0482C ). We further acknowledge support by the German Research Foundation and the Open Access Publication Funds of the Technische Universit{\"a}t Braunschweig.",
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AU - Bahnemann, Detlef W.

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N1 - Funding information: The authors gratefully acknowledge financial support from Deutsche Forschungsgemeinschaft (ADMFC/AOBJ: 622591) and Federal Ministry of Education and Research BMBF (Project “DuaSol” No. 03SF0482C). We further acknowledge support by the German Research Foundation and the Open Access Publication Funds of the Technische Universität Braunschweig. The authors gratefully acknowledge financial support from Deutsche Forschungsgemeinschaft (ADMFC/AOBJ: 622591 ) and Federal Ministry of Education and Research BMBF (Project “DuaSol” No. 03SF0482C ). We further acknowledge support by the German Research Foundation and the Open Access Publication Funds of the Technische Universität Braunschweig.

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N2 - The alkaline methanol electrooxidation reaction (MOR) in alkaline direct methanol fuel cells is still very little understood with regard to its electrochemical behavior. Theoretically, when using a rotating disk (RDE) as working electrode, the limiting current from an electrochemical reaction increases with the rotation rate as described by Levich. Contrary to this principle, the current resulting from the alkaline MOR does not increase, but decreases with rotation rate. In this work, we investigate the reason for this phenomenon using the method described by Nash and modified by Belman to quantify formaldehyde, a reaction intermediate of the alkaline methanol electrooxidation. The amount of formaldehyde is in direct relation to the rotation rate, proving that the current density loss can originate from an intensified removal of formaldehyde into the bulk solution. We analyse the influence of the electrolyte and methanol concentration on the formation of formaldehyde in order to investigate which conditions support the complete oxidation pathway and suppress the incomplete oxidation to formaldehyde. The concentration ratio as well as the absolute concentrations are of great importance for the pathways taking place. A low electrolyte concentration leads to an increase of the formaldehyde but decreasing the methanol concentration results in an absence of formaldehyde in the bulk solution.

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