Abstract
Introduction Degradation of a polymer electrolyte fuel cell (PEFC) caused by platinum (Pt) dissolution on the cathode remains a challenge for its durability in long-term applications. The cathode is repeatedly exposed to high potentials during ON-OFF cycles, which accelerates Pt dissolution. Sugawara et al. [1] reported that Pt dissolution was affected by the scan rate at which potential cycling was performed. The ex-situ analysis by ICP-MS[1]provided an average evaluation of the dissolution amount during one cycle or a given time period. It would be more helpful for specification of the dissolution mechanism in different potential regions, if the dissolution rate could be traced simultaneously with the dissolved species being identified. For this purpose, we employed a channel flow double electrode as an in-situ monitoring method, and investigated the dissolution behavior on a Pt electrode that underwent potential cycling at different scan rates. Experimental A channel flow double electrode (CFDE) consisted of a working electrode (WE) and a collector electrode (CE). The collection number (N) of the channel flow cell was 0.3, given the geometries shown in Figure 1.[2] In a prior work,[3] we proved that the submonolayer-level Pt dissolution on the WE under potential cycling could be detected on the CE. The current responses on the CE (collector current, I C) could be used as a detection parameter, from which the dissolution rate on the WE can be calculated.In this work, the WE was a thin film of Pt electroplated on a gold (Au) substrate. The solution was 0.5 M H2SO4 deaerated by argon gas. The average flow rate of the solution was 10 cm/s. The WE underwent potential cycling between 0.07 and 1.4 V (vs. SHE) at 1, 5, 20, 100, and 200 mV/s. A CE of Au was set at 0.3 V at which both Pt2+ and Pt4+ were reduced to Pt. Dissolution of Pt4+ was detected on a CE set at 0.7 V by reducing Pt4+ to Pt2+. All measurements were performed on a multi-channel potentiostat (PS-08, TOHO Technical Research, Japan) at room temperature. Results and discussion During a slow anodic scan (5 mV/s), both Pt2+ dissolution below 1.0 V and Pt4+ dissolution above 1.2 V are suppressed. This decline of Pt dissolution is due to surface passivation by Pt oxide, similar to that in potentiostatic conditions.[4] This result also suggests that surface passivation of Pt requires an excessive polarization such as a slow anodic scan.Interestingly, dissolution of Pt4+ is preponed as we slower the scan rate. Figure 2 shows the CVs of the WE (at 1 mV/s and 20 mV/s) and the I C recorded during an anodic scan on a CE set at 0.7 V. When the WE is scanned at 1 mV/s, the I C, representing detection of Pt4+, starts to increase at a lower potential. This shift of on-set potential of Pt4+ dissolution is only observed during a slow anodic scan. During a fast anodic scan (200 mV/s), the Pt4+ dissolution still starts around 1.2 V, though the dissolution rate tends to decrease. Thus, the place exchange between the O and Pt atoms[5] seems necessary for Pt4+dissolution above 1.2 V.However, the cathodic dissolution of Pt2+ from reduction of PtO2 is enhanced during a fast cathodic scan. The reduction rate of PtO2 is proportional to scan rate. As a result, more Pt2+ is produced when the PtO2 is being reduced at a faster cathodic potential shift. Therefore, in an operating PEFC, where the potential sweep on the cathode may be faster than 200 mV/s, cathodic dissolution is expected to be more severe. Interestingly, the ratio between cathodic dissolution of Pt2+ and reduction of PtO2in a cathodic scan decreases as we increase the scan rate. Reference Y. Sugawara, A.P. Yadav, A. Nishikata, T. Tsuru, ECS Trans., 16 (24), 117 (2009).H. Matsuda, J. Electroanal. Chem., 16, 153 (1968).Z. Wang, E. Tada, and A. Nishikata, J. Electrochem. Soc., 161(4), F380 (2014).X.P. Wang, R. Kumar, D.J. Myers, Electrochem. Solid-State Lett., 9, A225 (2006).G. Jerkiewicz, G. Vatankhah, J. Lessard, M.P. Soriaga, Y.S. Park, Electrochim. Acta., 49, 1451 (2004).
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