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Journal ArticleOPEN ACCESS

Ice Formation Processes in PEM Fuel Cell Catalyst Layers during Cold Startup Analyzed by Cryo-SEM

  • Tabe Y
  • Yamada K
  • Ichikawa R
  • et al.
Journal of The Electrochemical Society (2016) 163(10) F1139-F1145
DOI: 10.1149/2.1321609jes
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Abstract

© The Author(s) 2016.For further improvements in the startup ability below freezing and the durability of polymer electrolyte fuel cells, understanding the ice formation mechanism during cold startup is particularly significant. This study observes cross-sectional ice distributions in a catalyst layer (CL) during isothermal galvanostatic operation at -20°C using a cryo-scanning electron microscope. The effects of current density, cathode gas conditions, initial water content of the membrane, and cell temperature on the cold start characteristics and the ice formation process in the CL are evaluated. The observational results show that at higher current densities, the region with active ice formation moves from the membrane to the gas diffusion layer sides during the freezing period and vacant pores remain near the membrane even after cell shutdown, while the pores are completely filled with nearly-uniformly growing ice at lower current density operation. This is consistent with the experimental finding from the cold start characteristics that the estimated amount of ice accumulated in the cell until the shutdown decreases as the current density increases. Contrary to expectations, these changes are largely independent of cathode gas conditions, even with pure oxygen. Additional factors controlling the ice formation process are discussed based on the experimental results.

Figures

  • Table I. Experimental conditions of the cold start operation investigated here.
  • Figure 1. Cryo-SEM images of cross-sections of the cathode CL, (a) after the wet purge by nitrogen with 24% RH at 60◦C and cooling to −20◦C, and (b) after the shutdown of the 0.04 A cm−2 startup at −20◦C.
  • Figure 2. Cell voltages and resistances at three current densities for different operating durations at −20◦C, (a) 0.01 A cm−2 for early in the freezing and until the shutdown, (b) 0.04 A cm−2 for early in and halfway through the freezing, until the shutdown, and (c) 0.08 A cm−2 for early in the freezing and until the shutdown, (No. 1 to 3 in Table I).
  • Figure 3. Amounts of water produced throughout the operation, divided into three: the estimated residual water produced during the membrane rehydration, after the end of the rehydration till the shutdown, and the estimated water removed by the reactant gases at −20◦C, (No. 1 to 6 in Table I).
  • Figure 4. Cryo-SEM images of cross-sections of the CL after the operation in Fig. 2, (a) 0.04 A cm−2 for early and halfway in the freezing at the cathode side, after the shutdown at the cathode and anode sides (No. 2 in Table I), and (b) 0.01 A cm−2 and (c) 0.08 A cm−2 for early in the freezing and after the shutdown at the cathode side, (No. 1 and 3).
  • Figure 5. Cell voltages and resistances for different cathode gas conditions, (a) 0.08 A cm−2 with air at 1atm, 10% O2 at 2atm, and air at 2atm (No. 7 to 9 in Table I), and (b) 0.04 A cm−2 with pure oxygen and air at 1atm (No. 11 and 14).
  • Figure 6. Amounts of water produced throughout the operation, divided into three: the estimated residual water produced in the membrane rehydration, after the end of the rehydration till the shutdown, and the estimated water removed by the reactant gases for different cathode gas conditions, (a) air at 1atm, 10% O2 at 2atm, and air at 2atm (No. 7 to 9 in Table I), and (b) pure oxygen and air at 1atm (No. 10 to 15).
  • Figure 7. Cryo-SEM images of cross-sections of the cathode CL after the shutdown for different cathode gas conditions, (a) 0.08 A cm−2 with air at 2atm (No. 16 in Table I) and (b) 0.20 A cm−2 with oxygen (No. 17).

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CITATION STYLE

APA

Tabe, Y., Yamada, K., Ichikawa, R., Aoyama, Y., Suzuki, K., & Chikahisa, T. (2016). Ice Formation Processes in PEM Fuel Cell Catalyst Layers during Cold Startup Analyzed by Cryo-SEM. Journal of The Electrochemical Society, 163(10), F1139–F1145. https://doi.org/10.1149/2.1321609jes

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