CO Impact on the Stability Properties of PtxCoy Nanoparticles in PEM Fuel Cell Anodes: Mechanistic Insights

Cheah, Seng Kian; Sicardy, Olivier; Marinova, Maya; Guetaz, Laure; Lemaire, Olivier; Gélin, Patrick; Franco, Alejandro A.

Type de document :

Article dans une revue scientifique: Article original

DOI :

10.1149/2.039111jes

URL permanente :

http://hdl.handle.net/20.500.12210/11506

Titre :

CO Impact on the Stability Properties of PtxCoy Nanoparticles in PEM Fuel Cell Anodes: Mechanistic Insights

Auteur(s) :

Cheah, Seng Kian [Auteur]
Sicardy, Olivier [Auteur]
Marinova, Maya [Auteur]

Guetaz, Laure [Auteur]
Lemaire, Olivier [Auteur]
Gélin, Patrick [Auteur]
Franco, Alejandro A. [Auteur]

Titre de la revue :

Journal of the Electrochemical Society

Numéro :

158

Pagination :

B1358

Date de publication :

2011

Discipline(s) HAL :

Chimie/Catalyse

Résumé en anglais : [en]

Based on a multiscale modeling framework, we focus on understanding the impact of CO adsorption on the intrinsic stability properties of PtxCoy nanoparticles under PEMFC anode operating conditions. Firstly, CO adsorption ...
Lire la suite >Based on a multiscale modeling framework, we focus on understanding the impact of CO adsorption on the intrinsic stability properties of PtxCoy nanoparticles under PEMFC anode operating conditions. Firstly, CO adsorption effect on PtxCoy has been studied by using Monte Carlo (MC) simulation. Then, the MC results were coupled with a non-equilibrium thermodynamics kinetics model (MEMEPhys®) to simulate the effect of CO poisoning on the activity and durability of PtxCoy nanoparticles as HOR catalysts. The results are compared with simulations carried out on Pt, where potential self-oscillatory behaviour is observed and experimentally confirmed. The PtxCoy HOR activity and stability properties reveal to be strongly dependent on the nanoparticle size and composition. For certain nanoparticle sizes, simulations show that PtCo nanoparticles provide better CO tolerance than Pt3Co. However, the CO tolerance of PtCo degrades faster than that of Pt3Co in long-term operation. From both modeling and experimental approaches, it is demonstrated for the first time that this observation is due to the fact that CO adsorption enhances Cobalt dissolution.Lire moins >

Langue :

Anglais

Comité de lecture :

Oui

Audience :

Internationale

Vulgarisation :

Non

Collections :

Autres travaux scientifiques

Date de dépôt :

2019-06-17T08:43:26Z
2020-03-09T17:14:41Z

Numéro de version	Lien	Date de modification
2	20.500.12210/11506*	2020-03-09T17:09:56Z
1	20.500.12210/11506.1	2019-06-17T08:43:26Z

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CO Impact on the Stability Properties of ...

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RIS