Interfacial carbon dots introduced distribution-structure modulation of Pt loading on graphene towards enhanced electrocatalytic hydrogen evolution reaction

[Display omitted] To easily load Pt on smoothy graphene synthesized by cathodic exfoliation method and achieve adjacent plane distribution of Pt, carbon dots (CDs) are used to construct anchoring points to load highly dispersed Pt species due to strong interaction between CDs and Pt species. The com...

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Bibliographic Details
Published in:Journal of colloid and interface science 2024-02, Vol.656, p.214-224
Main Authors: Xiao, He, Bai, Meng, Zhao, Man, Fu, Zimei, Wang, Wenxiang, Zhao, Peipei, Ma, Jiamin, Zhang, Li, Zhang, Junming, He, Yingluo, Zhang, Jian, Jia, Jianfeng
Format: Article
Language:English
Subjects:
Carbon dot
Distribution-structure
Hydrogen evolution reaction
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Summary:[Display omitted] To easily load Pt on smoothy graphene synthesized by cathodic exfoliation method and achieve adjacent plane distribution of Pt, carbon dots (CDs) are used to construct anchoring points to load highly dispersed Pt species due to strong interaction between CDs and Pt species. The composite of Pt-CDs/graphene is synthesized via a continuous process of cathodic exfoliation-hydrothermal-impregnation-reduction. Characterization results indicate the distribution configuration of Pt varies from coated structure of CDs@Pt to dispersed configuration of CDs&Pt or Pt&CDs, then to wrapping configuration of Pt@CDs with increased amount of CDs. It’s found that suitable introduction of CDs promotes the adjacent plane distribution of Pt species. The obtained best Pt-4CDs/G shows the low overpotential of 36 mV (10 mA⋅cm−2) and high mass activity of 3747.8 mA mg−1 at −40 mV towards electrocatalytic hydrogen evolution reaction (HER), 9.2 times more active than that of Pt/C (406.2 mA mg−1). The superior HER performance of Pt-4CDs/G is attributed to its relatively adjacent plane distribution of Pt, which supports high electrochemically active surface area and more adjacent Pt sites for H* adsorption. Benefitting from that, the HER process for Pt-4CDs/G favorably follows the Tafel pathway, resulting in low hydrogen adsorption free energy and excellent HER activity.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2023.11.102