Identifying the Activity Origin of a Cobalt Single‐Atom Catalyst for Hydrogen Evolution Using Supervised Learning

Single‐atom catalysts (SACs) have become the forefront of energy conversion studies, but unfortunately, the origin of their activity and the interpretation of the synchrotron spectrograms of these materials remain ambiguous. Here, systematic density functional theory computations reveal that the edg...

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Published inAdvanced functional materials Vol. 31; no. 18
Main Authors Liu, Xinghui, Zheng, Lirong, Han, Chenxu, Zong, Hongxiang, Yang, Guang, Lin, Shiru, Kumar, Ashwani, Jadhav, Amol R., Tran, Ngoc Quang, Hwang, Yosep, Lee, Jinsun, Vasimalla, Suresh, Chen, Zhongfang, Kim, Seong‐Gon, Lee, Hyoyoung
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.05.2021
Subjects
Cobalt
Density functional theory
electrocatalysts
Energy conversion
Graphene
hydrogen evolution reaction
Hydrogen evolution reactions
machine learning
Materials science
Performance evaluation
Single atom catalysts
Spectrograms
Structural analysis
Supervised learning
Synchrotrons
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Summary:Single‐atom catalysts (SACs) have become the forefront of energy conversion studies, but unfortunately, the origin of their activity and the interpretation of the synchrotron spectrograms of these materials remain ambiguous. Here, systematic density functional theory computations reveal that the edge sites—zigzag and armchair—are responsible for the activity of the graphene‐based Co (cobalt) SACs toward hydrogen evolution reaction (HER). Then, edge‐rich (E)‐Co single atoms (SAs) were rationally synthesized guided by theoretical results. Supervised learning techniques are applied to interpret the measured synchrotron spectrum of E‐Co SAs. The obtained local environments of Co SAs, 65.49% of Co‐4N‐plane, 13.64% in Co‐2N‐armchair, and 20.86% in Co‐2N‐zigzag, are consistent with Athena fitting. Remarkably, E‐Co SAs show even better HER electrocatalytic performance than commercial Pt/C at high current density. Using the joint effort of theoretical modeling, thorough characterization of the catalysts aided by supervised learning, and catalytic performance evaluations, this study not only uncovers the activity origin of Co SACs for HER but also lays the cornerstone for the rational design and structural analysis of nanocatalysts. Single‐atom‐catalysts (SACs) are at the forefront of energy conversion research. Unfortunately, the origin of their activity and interpretation of these materials’ synchrotron spectrograms remain ambiguous. By theoretical modeling, catalytic characterization aided by supervised learning, and catalytic performance evaluations, this study uncovers the Co SACs’ activity origin of hydrogen evolution. It lays the cornerstone for the design and structural analysis of nanocatalysts.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202100547