Elucidating Pt/C and ionomer aggregation dynamics in the manufacturing of fuel cell catalyst layers: a discrete element method approach

IF 7.9 2区工程技术 Q1 CHEMISTRY, PHYSICAL

Journal of Power Sources Pub Date : 2025-09-24 DOI:10.1016/j.jpowsour.2025.238238

Sourab Barath Vijayaraghavan , Matthias Baldofski , Alejandro A. Franco

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Abstract

The production of fuel cells is bottle-necked by the prohibitive cost of one component – the catalyst layer. The goal of manufacturers has been to minimise Pt loading and maximise the electrochemical efficiency, at scale. A mesoscale model is sought-after, to describe the influence of common manufacturing parameters on the microstructure of fuel cell catalyst layers. In this work we propose a novel end-to-end mesoscale modeling workflow to capture the spatial aggregation of carbon support particles against an ionomer-based binder. We use the Discrete Element Method (DEM) to capture the co-aggregation of the carbon-support and binder, as a function of their inter-particle Derjaguin–Landau–Verwey–Overbeek (DLVO) interactions. This model provides insights in the variance in ionomer aggregation as a function of solvent composition. We observe a decrease in ionomer secondary aggregation with decreasing water content. This variance in the local catalyst – ionomer distribution was studied using various micro-structural descriptors.

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阐明燃料电池催化剂层制造过程中铂/碳和离聚体聚集动力学：一种离散元方法

燃料电池的生产受到一种成分——催化剂层的高昂成本的制约。制造商的目标是在规模上最小化Pt负载并最大化电化学效率。一个中尺度的模型被追捧，以描述常见的制造参数对燃料电池催化剂层微观结构的影响。在这项工作中，我们提出了一种新颖的端到端中尺度建模工作流程，以捕获碳支撑颗粒对基于离子的粘合剂的空间聚集。我们使用离散元方法（DEM）来捕捉碳载体和粘合剂的共聚集，作为它们粒子间derjaguin - landau - vervey - overbeek （DLVO）相互作用的函数。该模型提供了在离聚体聚集的变化作为溶剂组成的函数的见解。我们观察到，随着水含量的减少，离聚体的二次聚集减少。用不同的微观结构描述符研究了局部催化剂-离聚体分布的差异。

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来源期刊

Journal of Power Sources 工程技术-电化学

CiteScore

16.40

自引率

6.50%

发文量

1249

审稿时长

36 days

期刊介绍： The Journal of Power Sources is a publication catering to researchers and technologists interested in various aspects of the science, technology, and applications of electrochemical power sources. It covers original research and reviews on primary and secondary batteries, fuel cells, supercapacitors, and photo-electrochemical cells. Topics considered include the research, development and applications of nanomaterials and novel componentry for these devices. Examples of applications of these electrochemical power sources include: • Portable electronics • Electric and Hybrid Electric Vehicles • Uninterruptible Power Supply (UPS) systems • Storage of renewable energy • Satellites and deep space probes • Boats and ships, drones and aircrafts • Wearable energy storage systems