New insight of tailor-made graphene oxide for the formation of atomic Co-N sites toward hydrogen evolution reaction

The effect of basal plane oxygen functional groups of GO on the Co-N transition is investigated by tailoring the oxygen content and composition of oxygen functional groups on the basal plane of GO sheets. The high oxygen functional groups on the basal plane provide energetically favorable environmen...

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Bibliographic Details
Published in:Applied surface science 2021-10, Vol.563, p.150254, Article 150254
Main Authors: Jung, Jae Young, Hong, Yu Lim, Kim, Jeong-Gil, Kim, Min Ji, Kim, Young-Kwan, Kim, Nam Dong
Format: Article
Language:English
Subjects:
Atomic Co-N sites
Hydrogen evolution reaction
Tailor-made graphene oxide
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Summary:The effect of basal plane oxygen functional groups of GO on the Co-N transition is investigated by tailoring the oxygen content and composition of oxygen functional groups on the basal plane of GO sheets. The high oxygen functional groups on the basal plane provide energetically favorable environments for Co-N formation. The hydrogen evolution reaction (HER) activities correlate to the amounts of Co-N sites. [Display omitted] •Effect of basal plane oxygen functional groups on Co-N transition is investigated.•The adsorption of cobalt ions and Co-N transition are investigated by XPS and XAFS.•The Co-N transition is facilitated by oxygen functional groups on the basal plane.•The HER catalytic activity is closely related to the amounts of Co-N sites. The designed synthesis of graphene oxide (GO) for the formation of nitrogen-coordinated atomic metal sites (M−N−C) is crucial for developing efficient M−N−C catalysts. Here, the effect of basal plane oxygen functional groups of GO on the adsorption of cobalt ions and their Co-N transition is investigated by tailoring the oxygen content and composition of oxygen functional groups on the basal plane of GO sheets. The tailor-made GO shows that the specific oxygen functional groups, such as hydroxyl, epoxy, and carbonyl groups, can be efficiently incorporated with formation of defected structures on the basal plane of GO sheets rather than their edge. The adsorption of cobalt ions on the GO sheets and their transition to the Co-N state are systematically investigated by XPS and XAFS analyses. Annealing temperature-controlled experiments reveal that the incorporation of nitrogen around cobalt atoms is facilitated by the increased number of oxygen functional groups on the basal plane rather than those on the edge of GO sheets, which provide energetically favorable environments for Co-N formation. The hydrogen evolution reaction (HER) activities of the resulting cobalt atom-immobilized and annealed GO (Co/GOx-T) catalysts correlate to the degree of Co-N saturation, while also demonstrating excellent HER catalytic durability.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2021.150254