Elucidating effects of catalyst loadings and porous transport layer morphologies on operation of proton exchange membrane water electrolyzers

Kulkarni D. ¹O'Brien M. ¹Zenyuk I.V. ¹Huynh A. ²Satjaritanun P. ²Shimpalee S. ³Parkinson D. ⁴Danilovic N. ⁴Shevchenko P. ⁵DeCarlo F. ⁵Ayers K.E. ⁶Capuano C.⁶

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作者信息

1. Department of Material Science and Engineering University of California Irvine
2. National Fuel Cell Research Center University of California Irvine
3. Department of Chemical Engineering University of South Carolina
4. Energy Technologies Area Energy Conversion Group Lawrence Berkeley National Laboratory
5. X-ray Science Division Argonne National Laboratory
6. Nel Hydrogen
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Abstract

? 2022 Elsevier B.V.Producing green hydrogen efficiently via proton exchange membrane water electrolysis (PEMWE) is the key for achieving decarbonization targets. Iridium catalyst is expensive, and it is important to minimize its use and to optimize interface between Ir and ionomer or water for higher utilization of catalyst in oxygen evolution reaction. In this paper, x-ray computed tomography along with electrochemical and modeling techniques are used to characterize the interface for two different porous transport layers (PTLs) and catalyst layers at various loadings. We show that low porosity sintered PTLs exhibit higher interfacial contact with the catalyst and the membrane that results in improved kinetics. Radiography and modeling results indicate that oxygen taking multiple transport pathways through the PTL results in slug flow through the channels that reduces mass transport overpotential. Based on the results, we suggest design guidelines for high efficiency and durable PEMWE and their components.

Key words

Catalyst layers/Durability analysis/Lattice Boltzmann method modeling/Proton exchange membrane water electrolysis/Triple phase contact area/X-ray computed tomography

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出版年

2022

Applied Catalysis

ISSN：0926-3373

被引量41

参考文献量60

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