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Surface-Modified Carbon Nanotubes with Ultrathin Co3O4 Layer for Enhanced Oxygen Evolution Reaction

Authors
Lee, KangpyoKang, SukhyunRyu, Jeong HoJeon, HayunKim, MinjuKim, Young-KwangSong, TaeseupHan, HyukSuMhin, SungwookKim, Kang Min
Issue Date
Dec-2023
Publisher
American Chemical Society
Keywords
alkaline water electrolysis; atomic layer deposition; carbon nanotube; oxygen evolution reaction; pulse laser ablation
Citation
ACS Applied Materials & Interfaces, v.15, no.50, pp 58377 - 58387
Pages
11
Indexed
SCIE
SCOPUS
Journal Title
ACS Applied Materials & Interfaces
Volume
15
Number
50
Start Page
58377
End Page
58387
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/194371
DOI
10.1021/acsami.3c13220
ISSN
1944-8244
1944-8252
Abstract
Alkaline water electrolysis is a vital technology for sustainable and efficient hydrogen production. However, the oxygen evolution reaction (OER) at the anode suffers from sluggish kinetics, requiring overpotential. Precious metal-based electrocatalysts are commonly used but face limitations in cost and availability. Carbon nanostructures, such as carbon nanotubes (CNTs), offer promising alternatives due to their abundant active sites and efficient charge-transfer properties. Surface modification of CNTs through techniques such as pulsed laser ablation in liquid media (PLAL) can enhance their catalytic performance. In this study, we investigate the role of surface-modified carbon (SMC) as a support to increase the active sites of transition metal-based electrocatalysts and its impact on electrocatalytic performance for the OER. We focus on Co3O4@SMC heterostructures, where an ultrathin layer of Co3O4 is deposited onto SMCs using a combination of PLAL and atomic layer deposition. A comparative analysis with aggregated Co3O4 and Co3O4@pristine CNTs reveals the superior OER performance of Co3O4@SMC. The optimized Co3O4@SMC exhibits a 25.6% reduction in overpotential, a lower Tafel slope, and a significantly higher turnover frequency (TOF) in alkaline water splitting. The experimental results, combined with density functional theory (DFT) calculations, indicate that these improvements can be attributed to the high electrocatalytic activity of Co3O4 as active sites achieved through the homogeneous distribution on SMCs. The experimental methodology, morphology, composition, and their correlation with activity and stability of Co3O4@SMC for the OER in alkaline media are discussed in detail. This study contributes to the understanding of SMC-based heterostructures and their potential for enhancing electrocatalytic performance in alkaline water electrolysis.
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