2013
DOI: 10.1149/2.037309jes
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Carbonate and Bicarbonate Ion Transport in Alkaline Anion Exchange Membranes

Abstract: Anion exchange membranes (AEMs) are being developed for potential use in fuel cell systems which include portable power applications. In a fuel cell, these membranes transport hydroxide ions from the cathode to the anode. If carbon dioxide is present, carbonate and bicarbonate ions can form, displacing the hydroxide ions. Among the challenges this presents, the carbonate and bicarbonate are less mobile than the hydroxide and therefore the ionic conductivity of the membrane suffers. A procedure is outlined to t… Show more

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Cited by 73 publications
(65 citation statements)
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“…This performance characteristic, avoiding cathode dry out even at high current density and reduced RH feeds, may be different than observed with AEMFCs containing other materials because of the novelty of the electrode fabrication method used in this work as well as the use of the powder AEI and high ionic conductivity of the ETFE-based AEM used in this study; the water mobility and resulting water back diffusion are, therefore, significantly enhanced [15,17], leading to balanced anode and cathode water with avoidance of anode flooding and cathode dry out. Fig.…”
Section: Tj Omasta Et Al / Journal Of Power Sources XXX (2017) 1e9mentioning
confidence: 67%
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“…This performance characteristic, avoiding cathode dry out even at high current density and reduced RH feeds, may be different than observed with AEMFCs containing other materials because of the novelty of the electrode fabrication method used in this work as well as the use of the powder AEI and high ionic conductivity of the ETFE-based AEM used in this study; the water mobility and resulting water back diffusion are, therefore, significantly enhanced [15,17], leading to balanced anode and cathode water with avoidance of anode flooding and cathode dry out. Fig.…”
Section: Tj Omasta Et Al / Journal Of Power Sources XXX (2017) 1e9mentioning
confidence: 67%
“…To avoid cathode dry-out and/or anode flooding in AEMFCs, it would be preferable for the AEM to have high water back diffusion. However, many AEMs in the literature do not have the same efficient phase separation as Nafion ® and limited OH À conductivity (Table 1), which translates directly to low water backdiffusion rates [15,17]. Therefore, engineering solutions have been explored in a number of studies, including running commercial systems at very low current density [16], pressurizing the gas streams, or even feeding condensed water through the cathode [10] e none of which are tenable long-term solutions to high performing AEMFCs.…”
Section: Introductionmentioning
confidence: 99%
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“…The effective cathode resistance (R c ) against water transport from the cathode inlet to the cathode catalyst layer can be described as [15] Note that the resistance of vapor absorption into AEM ionomers is not included in calculating the effective resistance here. The expression for the water transport resistance in the ionomer and gas phases can be referenced to the previous work.…”
Section: Variablementioning
confidence: 99%
“…16 However, AEMFCs still suffer a decline in performance due to bicarbonate/carbonate formation in the membrane and catalyst layers (CLs) leading to additional ohmic and kinetic losses. [13][14][15] In an AEMFC, the following electrochemical reactions occur in the CLs as follows:Net :Hydrogen combines with hydroxide ions to produce water in the anode. Oxygen reacts with water to generate hydroxide ions in the cathode.…”
mentioning
confidence: 99%