TY - JOUR
T1 - Operando Fe dissolution in Fe-N-C electrocatalysts during acidic oxygen reduction
T2 - impact of local pH change
AU - Pedersen, Angus
AU - Kumar, Kavita
AU - Ku, Yu Ping
AU - Martin, Vincent
AU - Dubau, Laetitia
AU - Santos, Keyla Teixeira
AU - Barrio, Jesús
AU - Saveleva, Viktoriia A.
AU - Glatzel, Pieter
AU - Paidi, Vinod K.
AU - Li, Xiaoyan
AU - Hutzler, Andreas
AU - Titirici, Maria Magdalena
AU - Bonnefont, Antoine
AU - Cherevko, Serhiy
AU - Stephens, Ifan E.L.
AU - Maillard, Frédéric
N1 - Publisher Copyright:
© 2024 The Royal Society of Chemistry.
PY - 2024/1/1
Y1 - 2024/1/1
N2 - Atomic Fe in N-doped C (Fe-N-C) catalysts provide the most promising non-precious metal O2 reduction activity at the cathodes of proton exchange membrane fuel cells. However, one of the biggest remaining challenges to address towards their implementation in fuel cells is their limited durability. Fe demetallation has been suggested as the primary initial degradation mechanism. However, the fate of Fe under different operating conditions varies. Here, we monitor operando Fe dissolution of a highly porous and >50% FeNx electrochemical utilization Fe-N-C catalyst in 0.1 M HClO4, under O2 and Ar at different temperatures, in both flow cell and gas diffusion electrode (GDE) half-cell coupled to inductively coupled plasma mass spectrometry (ICP-MS). By combining these results with pre- and post-mortem analyses, we demonstrate that in the absence of oxygen, Fe cations diffuse away within the liquid phase. Conversely, at −15 mA cm−2geo and more negative O2 reduction currents, the Fe cations reprecipitate as Fe-oxides. We support our conclusions with a microkinetic model, revealing that the local pH in the catalyst layer predominantly accounts for the observed trend. Even at a moderate O2 reduction current density of −15 mA cm−2geo at 25 °C, a significant H+ consumption and therefore pH increase (pH = 8-9) within the bulk Fe-N-C layer facilitate precipitation of Fe cations. This work provides a unified view on the Fe dissolution degradation mechanism for a model Fe-N-C in both high-throughput flow cell and practical operating GDE conditions, underscoring the crucial role of local pH in regulating the stability of the active sites.
AB - Atomic Fe in N-doped C (Fe-N-C) catalysts provide the most promising non-precious metal O2 reduction activity at the cathodes of proton exchange membrane fuel cells. However, one of the biggest remaining challenges to address towards their implementation in fuel cells is their limited durability. Fe demetallation has been suggested as the primary initial degradation mechanism. However, the fate of Fe under different operating conditions varies. Here, we monitor operando Fe dissolution of a highly porous and >50% FeNx electrochemical utilization Fe-N-C catalyst in 0.1 M HClO4, under O2 and Ar at different temperatures, in both flow cell and gas diffusion electrode (GDE) half-cell coupled to inductively coupled plasma mass spectrometry (ICP-MS). By combining these results with pre- and post-mortem analyses, we demonstrate that in the absence of oxygen, Fe cations diffuse away within the liquid phase. Conversely, at −15 mA cm−2geo and more negative O2 reduction currents, the Fe cations reprecipitate as Fe-oxides. We support our conclusions with a microkinetic model, revealing that the local pH in the catalyst layer predominantly accounts for the observed trend. Even at a moderate O2 reduction current density of −15 mA cm−2geo at 25 °C, a significant H+ consumption and therefore pH increase (pH = 8-9) within the bulk Fe-N-C layer facilitate precipitation of Fe cations. This work provides a unified view on the Fe dissolution degradation mechanism for a model Fe-N-C in both high-throughput flow cell and practical operating GDE conditions, underscoring the crucial role of local pH in regulating the stability of the active sites.
UR - http://www.scopus.com/inward/record.url?scp=85200493014&partnerID=8YFLogxK
U2 - 10.1039/d4ee01995d
DO - 10.1039/d4ee01995d
M3 - Article
C2 - 39205876
AN - SCOPUS:85200493014
SN - 1754-5692
JO - Energy and Environmental Science
JF - Energy and Environmental Science
ER -