Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging

Daehee Yang; Young Hoon Kim; Hyo June Lee; Sang Hyeok Yang; Min Hyoung Jung; Eun Byeol Park; Hang Sik Kim; Yerin Jeon; Yuseong Heo; Ka Hyun Kim; Sungyong Cho; Yun Sik Kang; Ki Kang Kim; Hangil Lee; Sung Dae Yim; Jae Hyuck Jang; Sungchul Lee; Young Min Kim

doi:10.1016/j.apcatb.2025.125911

Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging

Daehee Yang
, Young Hoon Kim
, Hyo June Lee
, Sang Hyeok Yang
, Min Hyoung Jung
, Eun Byeol Park
, Hang Sik Kim
, Yerin Jeon
, Yuseong Heo
, Ka Hyun Kim
, Sungyong Cho
, Yun Sik Kang
, Ki Kang Kim
, Hangil Lee
, Sung Dae Yim
, Jae Hyuck Jang
, Sungchul Lee
, Young Min Kim

Research output: Contribution to journal › Article › peer-review

Abstract

To improve the performance of proton-exchange membrane fuel cells (PEMFCs), the control of the spatial distribution of ionomer–Pt alloy catalysts on porous carbon supports is crucial because changes in their morphological and geometrical distributions are relevant to the performance degradation of PEMFCs upon operation. However, their changes remain poorly understood due to the absence of characterization tools with sufficient chemical sensitivity and spatial resolution. Here, an efficient machine learning-assisted electron energy loss spectroscopy is introduced to interpret cycling-induced morphological changes of the cathode at the nanoscale. This approach allows the reliable visualization of the three distinctive components of Pt alloy catalysts, ionomers, and carbon in the electrode. Furthermore, based on large data interpretation, changes in the ionomer–Pt alloy distribution and ionomer coverage on the carbon support can be statistically assessed in relation to the degree of structural degradation of the components upon cycling.

Original language	English
Article number	125911
Journal	Applied Catalysis B: Environmental
Volume	382
DOIs	https://doi.org/10.1016/j.apcatb.2025.125911
State	Published - Mar 2026
Externally published	Yes

Funding

Daehee Yang, Young-Hoon Kim, and Hyo June Lee have contributed equally to this work. This study was supported by the Nano & Material Technology Development Program through the National Research Foundation of Korea (NRF), funded by the Ministry of Science and ICT ( RS-2024–00444182 , 50 %) and the Technology Innovation Program ( RS-2024–00433399 ), funded by the Ministry of Trade, Industry & Energy ( MOTIE , Korea). We acknowledge the support of Hyundai Motor Company. This work was supported by the National Research Foundation of Korea ( NRF ) grant ( RS-2024–00444986 and RS-2023-NR076943 ) funded by the Korean government in Korea. This work was supported by the Institute for Basic Science ( IBS-R036-D1 ) in Korea and the Korea Basic Science Institute under the basic science research program (Project No. C 524200 ) supervised by the Ministry of Science and ICT . K.K.K. acknowledges support from the Basic Science Research through the National Research Foundation of Korea (NRF), which was funded by the Ministry of Science, ICT and Future Planning, and the Korean government (MSIT) ( 2022R1A2C2091475 and RS-2024-00439520 ).

Keywords

Electron spectroscopic imaging
Ionomer
Machine learning
Membrane electrode assembly
Proton-exchange membrane fuel cells

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10.1016/j.apcatb.2025.125911

Cite this

Yang, D., Kim, Y. H., Lee, H. J., Yang, S. H., Jung, M. H., Park, E. B., Kim, H. S., Jeon, Y., Heo, Y., Kim, K. H., Cho, S., Kang, Y. S., Kim, K. K., Lee, H., Yim, S. D., Jang, J. H., Lee, S., & Kim, Y. M. (2026). Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging. Applied Catalysis B: Environmental, 382, Article 125911. https://doi.org/10.1016/j.apcatb.2025.125911

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title = "Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging",

abstract = "To improve the performance of proton-exchange membrane fuel cells (PEMFCs), the control of the spatial distribution of ionomer–Pt alloy catalysts on porous carbon supports is crucial because changes in their morphological and geometrical distributions are relevant to the performance degradation of PEMFCs upon operation. However, their changes remain poorly understood due to the absence of characterization tools with sufficient chemical sensitivity and spatial resolution. Here, an efficient machine learning-assisted electron energy loss spectroscopy is introduced to interpret cycling-induced morphological changes of the cathode at the nanoscale. This approach allows the reliable visualization of the three distinctive components of Pt alloy catalysts, ionomers, and carbon in the electrode. Furthermore, based on large data interpretation, changes in the ionomer–Pt alloy distribution and ionomer coverage on the carbon support can be statistically assessed in relation to the degree of structural degradation of the components upon cycling.",

keywords = "Electron spectroscopic imaging, Ionomer, Machine learning, Membrane electrode assembly, Proton-exchange membrane fuel cells",

author = "Daehee Yang and Kim, \{Young Hoon\} and Lee, \{Hyo June\} and Yang, \{Sang Hyeok\} and Jung, \{Min Hyoung\} and Park, \{Eun Byeol\} and Kim, \{Hang Sik\} and Yerin Jeon and Yuseong Heo and Kim, \{Ka Hyun\} and Sungyong Cho and Kang, \{Yun Sik\} and Kim, \{Ki Kang\} and Hangil Lee and Yim, \{Sung Dae\} and Jang, \{Jae Hyuck\} and Sungchul Lee and Kim, \{Young Min\}",

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year = "2026",

month = mar,

doi = "10.1016/j.apcatb.2025.125911",

language = "English",

volume = "382",

journal = "Applied Catalysis B: Environmental",

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Yang, D, Kim, YH, Lee, HJ, Yang, SH, Jung, MH, Park, EB, Kim, HS, Jeon, Y, Heo, Y, Kim, KH, Cho, S, Kang, YS, Kim, KK, Lee, H, Yim, SD, Jang, JH, Lee, S & Kim, YM 2026, 'Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging', Applied Catalysis B: Environmental, vol. 382, 125911. https://doi.org/10.1016/j.apcatb.2025.125911

TY - JOUR

T1 - Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging

AU - Yang, Daehee

AU - Kim, Young Hoon

AU - Lee, Hyo June

AU - Yang, Sang Hyeok

AU - Jung, Min Hyoung

AU - Park, Eun Byeol

AU - Kim, Hang Sik

AU - Jeon, Yerin

AU - Heo, Yuseong

AU - Kim, Ka Hyun

AU - Cho, Sungyong

AU - Kang, Yun Sik

AU - Kim, Ki Kang

AU - Lee, Hangil

AU - Yim, Sung Dae

AU - Jang, Jae Hyuck

AU - Lee, Sungchul

AU - Kim, Young Min

PY - 2026/3

Y1 - 2026/3

N2 - To improve the performance of proton-exchange membrane fuel cells (PEMFCs), the control of the spatial distribution of ionomer–Pt alloy catalysts on porous carbon supports is crucial because changes in their morphological and geometrical distributions are relevant to the performance degradation of PEMFCs upon operation. However, their changes remain poorly understood due to the absence of characterization tools with sufficient chemical sensitivity and spatial resolution. Here, an efficient machine learning-assisted electron energy loss spectroscopy is introduced to interpret cycling-induced morphological changes of the cathode at the nanoscale. This approach allows the reliable visualization of the three distinctive components of Pt alloy catalysts, ionomers, and carbon in the electrode. Furthermore, based on large data interpretation, changes in the ionomer–Pt alloy distribution and ionomer coverage on the carbon support can be statistically assessed in relation to the degree of structural degradation of the components upon cycling.

AB - To improve the performance of proton-exchange membrane fuel cells (PEMFCs), the control of the spatial distribution of ionomer–Pt alloy catalysts on porous carbon supports is crucial because changes in their morphological and geometrical distributions are relevant to the performance degradation of PEMFCs upon operation. However, their changes remain poorly understood due to the absence of characterization tools with sufficient chemical sensitivity and spatial resolution. Here, an efficient machine learning-assisted electron energy loss spectroscopy is introduced to interpret cycling-induced morphological changes of the cathode at the nanoscale. This approach allows the reliable visualization of the three distinctive components of Pt alloy catalysts, ionomers, and carbon in the electrode. Furthermore, based on large data interpretation, changes in the ionomer–Pt alloy distribution and ionomer coverage on the carbon support can be statistically assessed in relation to the degree of structural degradation of the components upon cycling.

KW - Electron spectroscopic imaging

KW - Ionomer

KW - Machine learning

KW - Membrane electrode assembly

KW - Proton-exchange membrane fuel cells

UR - https://www.scopus.com/pages/publications/105014812281

U2 - 10.1016/j.apcatb.2025.125911

DO - 10.1016/j.apcatb.2025.125911

M3 - Article

AN - SCOPUS:105014812281

SN - 0926-3373

VL - 382

JO - Applied Catalysis B: Environmental

JF - Applied Catalysis B: Environmental

M1 - 125911

ER -

Integrated probing of cycling-induced degradation of multi-component electrode in hydrogen fuel cells via machine learning-empowered spectroscopic imaging

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Keywords

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