Product Distributions and Efficiencies for Ethanol Oxidation in a Proton Exchange Membrane Electrolysis Cell

Abstract: The stoichiometry, efficiency, and product distribution for ethanol oxidation in fuel cell hardware has been determined at 80 • C for commercial Pt/C, PtRu/C and PtSn/C anode catalysts. The amounts of ethanol consumed and acetic acid and acetaldehyde produced were determined by proton NMR spectroscopy while CO 2 was measured with a non-dispersive infrared CO 2 monitor. The Pt/C catalyst was most selective for the complete oxidation of ethanol to CO 2 at all potentials and therefore produced the highest number … Show more

“…This avoids inaccuracies that arise due to the chemical reaction of ethanol with oxygen when measurements are made in a DEFC. 15 Chemical analysis of the cell exhaust by nuclear magnetic resonance (NMR) and infrared (IR) spectrometry has been reported F480 Journal of The Electrochemical Society, 165 (7) F479-F483 (2018) previously for the same anodes, 6,8 with the accuracy of n av verified by the mass and charge balances, and agreement of values obtained from the amount of ethanol consumed and the product distribution.…”

“…6,8 Catalyst suspensions, prepared by dispersing the catalyst in a 1:1 mixture of 1-propanol and Nafion solution (Dupont; 5% Nafion) by sonication for 3 h, were spread onto Toray carbon fiber paper (CFP; TGP-H-090). Metal loadings of 3.2 mg cm −2 and Nafion loadings of ca.…”

“…6,8 This included flushing the cell with water, operating with ethanol at 0.7 V for at least 2 h and then recording polarization curves several times between 0.1 V and 0.7 V (0.05 V steps for 300 s). When applying the electrochemical method (Eq.…”

“…The procedures for determining n av by chemical analysis have been previously described. 6,8 The cell was operated at constant potential with an ethanol flow rate of 0.2 mL min −1 . CO 2 was measured in real time with a commercial non-dispersive infrared CO 2 monitor (Telaire 7001), while residual ethanol, acetic acid, and acetaldehyde in a sample of the liquid exiting the cell were measure by proton NMR spectrometry.…”

“…4,7 n av = n i· f i [4] where n i is the number of electrons transferred to form product i and f i is the fraction of ethanol converted to product i (CO 2 , acetic acid and acetaldehyde account for >99% of the ethanol consumed 8 ). Various experimental methods are available for measuring n av , including analysis of the amount of ethanol consumed, 9,10 the product distribution, 7,10 and several electrochemical methods.…”

Determination of the Stoichiometry of Ethanol Oxidation from the Flow Rate Dependence of the Current in a Proton Exchange Membrane Electrolysis Cell

“…This avoids inaccuracies that arise due to the chemical reaction of ethanol with oxygen when measurements are made in a DEFC. 15 Chemical analysis of the cell exhaust by nuclear magnetic resonance (NMR) and infrared (IR) spectrometry has been reported F480 Journal of The Electrochemical Society, 165 (7) F479-F483 (2018) previously for the same anodes, 6,8 with the accuracy of n av verified by the mass and charge balances, and agreement of values obtained from the amount of ethanol consumed and the product distribution.…”

“…6,8 Catalyst suspensions, prepared by dispersing the catalyst in a 1:1 mixture of 1-propanol and Nafion solution (Dupont; 5% Nafion) by sonication for 3 h, were spread onto Toray carbon fiber paper (CFP; TGP-H-090). Metal loadings of 3.2 mg cm −2 and Nafion loadings of ca.…”

“…6,8 This included flushing the cell with water, operating with ethanol at 0.7 V for at least 2 h and then recording polarization curves several times between 0.1 V and 0.7 V (0.05 V steps for 300 s). When applying the electrochemical method (Eq.…”

“…The procedures for determining n av by chemical analysis have been previously described. 6,8 The cell was operated at constant potential with an ethanol flow rate of 0.2 mL min −1 . CO 2 was measured in real time with a commercial non-dispersive infrared CO 2 monitor (Telaire 7001), while residual ethanol, acetic acid, and acetaldehyde in a sample of the liquid exiting the cell were measure by proton NMR spectrometry.…”

“…4,7 n av = n i· f i [4] where n i is the number of electrons transferred to form product i and f i is the fraction of ethanol converted to product i (CO 2 , acetic acid and acetaldehyde account for >99% of the ethanol consumed 8 ). Various experimental methods are available for measuring n av , including analysis of the amount of ethanol consumed, 9,10 the product distribution, 7,10 and several electrochemical methods.…”

Determination of the Stoichiometry of Ethanol Oxidation from the Flow Rate Dependence of the Current in a Proton Exchange Membrane Electrolysis Cell

Insights and Activation Energy Surface of the Dehydrogenation of C₂H_xO Species in Ethanol Oxidation Reaction on Ir(100)

Upgrading of Ethanol to 1,1‐Diethoxyethane by Proton‐Exchange Membrane Electrolysis