Titel
New Insights into the Metallization of Graphene-Supported Composite Materials─from 3D Cu-Grown Structures to Free-Standing Electrodeposited Porous Ni Foils
Autor*in
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Abstract
The conductivity and the state of the surface of supports are of vital importance for metallization via electrodeposition. In this study, we show that the metallization of a carbon fiber-reinforced polymer (CFRP) can be carried out directly if the intermediate graphene oxide (GO) layer is chemically reduced on the CFRP surface. Notably, this approach utilizing only the chemically reduced GO as a conductive support allows us to obtain insights into the interaction of rGO and the electrodeposited metal. Our study reveals that under the same contact current experimental conditions, the electrodeposition of Cu and Ni on rGO follows significantly different deposition modes, resulting in the formation of three-dimensional (3D) and free-standing metallic foils, respectively. Considering that Ni adsorption energy is larger than Ni cohesive energy, it is expected that the adhesion of Ni on rGO@CFRP is enhanced compared to Cu. In contrast, the adhesion of deposited Ni is reduced, suggesting diffusion of H+ between rGO and CFRP, which promotes the hydrogen evolution reaction (HER) and results in the formation of free-standing Ni foils. We ascribe this phenomenon to the unique properties of rGO and the nature of Cu and Ni deposition from electrolytic baths. In the latter, the high adsorption energy of Ni on defective rGO along with HER is the key factor for the formation of the porous layer and free-standing foils.
Stichwort
Carbon fiberCompositesDepositionLayersMetals
Objekt-Typ
Sprache
Englisch [eng]
Persistent identifier
Erschienen in
Titel
ACS Omega
Band
7
Ausgabe
5
ISSN
2470-1343
Erscheinungsdatum
2022
Seitenanfang
4352
Seitenende
4362
Publication
American Chemical Society (ACS)
Projekt
Kod / Identifikator
COMET
Projekt
Kod / Identifikator
BIH 07/2019
Fördergeber
Erscheinungsdatum
2022
Zugänglichkeit
Rechteangabe
© 2022 The Authors
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