2017
DOI: 10.1149/2.0101704jes
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Degradation Mechanisms of Carbon Supports under Hydrogen Passivation Startup and Shutdown Process for PEFCs

Abstract: The use of a hydrogen purge for startup and shutdown (H 2 -SU/SD) process of polymer electrolyte fuel cells has been proposed, which suppresses the generation of internal current during the SU/SD, process so-called "reverse current", and the severe carbon oxidation reaction (COR) in the cathode. However it was found that the COR was still caused during this H2-SU/SD process, even though it was less severe than that during the usual SU/SD process, i.e., the anode gas was successively cycled between air and H 2 … Show more

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Cited by 29 publications
(21 citation statements)
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“…To emulate carbon corrosion, which happens especially during cell start‐up/shutdown where the cell is subject to high voltages caused by a hydrogen/air wavefront, [ 181,182 ] cells are cycled at higher voltages between 1 and 1.5 V for around 5000 cycles. [ 174 ] The result of extended cycling at extreme voltages includes the loss of oxygen‐containing functional groups on the surface of supports, [ 159 ] formation of gases like CO and CO 2 , [ 183 ] as well as increased cracking of the CL [ 184,185 ] and overall loss of carbon material.…”
Section: Catalyst Layer Performance Characterizationmentioning
confidence: 99%
“…To emulate carbon corrosion, which happens especially during cell start‐up/shutdown where the cell is subject to high voltages caused by a hydrogen/air wavefront, [ 181,182 ] cells are cycled at higher voltages between 1 and 1.5 V for around 5000 cycles. [ 174 ] The result of extended cycling at extreme voltages includes the loss of oxygen‐containing functional groups on the surface of supports, [ 159 ] formation of gases like CO and CO 2 , [ 183 ] as well as increased cracking of the CL [ 184,185 ] and overall loss of carbon material.…”
Section: Catalyst Layer Performance Characterizationmentioning
confidence: 99%
“…During this transient phenomenon, the local cathode potential downstream (i.e., the cathode potential vs the reference electrode downstream) became higher, and the measured highest value exceeded 1.5 V, as shown in Figure 9a. As strategies in the balance of plant system during start-up and shut-down, controlling the cathode atmosphere to reduce the amount of oxygen in the cathode, [80,81] and controlling the cell voltage to prevent the cathode potential from rising [82] were proposed. As the fuel gas is introduced into the anode flow field, the local anode potential upstream decreases from ≈1 V to ≈0 V. This induces an increase in the cell voltage from ≈0 V to 1 V. Since the cell voltage is shared throughout the cell, the potential difference between the anode and cathode downstream is forced to increase to ≈1 V. Until the fuel gas appears, both the anode and cathode sides contain oxygen downstream, and the applied voltage drives this area to act as an oxygen pump, that is, oxygen reduction at the anode side and oxygen evolution at the cathode side.…”
Section: Inhomogeneity During the Start-up Transientmentioning
confidence: 99%
“…Based on the insight of this mechanism, several strategies that involved the operational technique and the material design were proposed to mitigate cathode degradation. As strategies in the balance of plant system during start‐up and shut‐down, controlling the cathode atmosphere to reduce the amount of oxygen in the cathode, and controlling the cell voltage to prevent the cathode potential from rising were proposed. As strategies that involve the material design, the addition of an oxygen evolution reaction (OER) catalyst, and the use of a corrosion‐resistant catalyst support at the cathode side were proposed.…”
Section: Degradation Phenomena Of Electrocatalysts With a Rise Of Elementioning
confidence: 99%
“…Consequently, some carbon oxide species could form and be available for oxidation during the reduction of PtOx causing the artifact peak. Another alternative explanation could be linked to the study by Yamashita et al [41]. The authors investigated carbon corrosion mechanisms during shut-down and start-up procedures while varying the atmosphere in the WE and formulated three different carbon corrosion mechanisms correlated to PtOx reduction.…”
Section: Introductionmentioning
confidence: 99%