TY - JOUR
T1 - Enhanced Electrochemical CO2 Reduction of Cu@CuxO Nanoparticles Decorated on 3D Vertical Graphene with Intrinsic sp3-type Defect
AU - Ma, Zhipeng
AU - Tsounis, Constantine
AU - Kumar, Priyank V.
AU - Han, Zhaojun
AU - Wong, Roong Jien
AU - Toe, Cui Ying
AU - Zhou, Shujie
AU - Bedford, Nicholas M.
AU - Thomsen, Lars
AU - Ng, Yun Hau
AU - Amal, Rose
N1 - Publisher Copyright:
© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
PY - 2020/6/1
Y1 - 2020/6/1
N2 - Defective 3D vertical graphene (VG) with a relatively large surface area, high defect density, and increased surface electrons is synthesized via a scalable plasma enhanced chemical vapor deposition method, together with a postsynthesis Ar-plasma treatment (VG-Ar). Subsequently, Cu@CuxO nanoparticles are deposited onto VG-Ar (Cu/VG-Ar) through a galvanostatic pulsed electrodeposition method. These Cu@CuxO nanocatalyst systems exhibit a superior electrochemical CO2 reduction performance when compared to Cu-based catalysts supported on commercial graphene paper or pristine VG without postsynthesis Ar-plasma treatment. The Cu/VG-Ar achieves the highest CO2 reduction Faradaic efficiency of 60.6% (83.5% of which are attributed to liquid products, i.e., formate, ethanol, and n-propanol) with a 5.6 mA cm−2 partial current density at −1.2 V versus reversible hydrogen electrode (RHE). The improved CO2 reduction performance of Cu/VG-Ar originates from the well-dispersed Cu@CuxO nanoparticles deposited on the defective VG-Ar. The intrinsic carbon defects on VG-Ar can suppress the hydrogen evolution reaction as well as tune the interaction between VG and Cu@CuxO, thus impeding the excessive oxidation of Cu2O species deposited on VG-Ar. The defective VG-Ar and stabilized Cu@CuxO enhances CO2 adsorption and promotes electron transfer to the adsorbed CO2 and intermediates on the catalyst surface, thus improving the overall CO2 reduction performance.
AB - Defective 3D vertical graphene (VG) with a relatively large surface area, high defect density, and increased surface electrons is synthesized via a scalable plasma enhanced chemical vapor deposition method, together with a postsynthesis Ar-plasma treatment (VG-Ar). Subsequently, Cu@CuxO nanoparticles are deposited onto VG-Ar (Cu/VG-Ar) through a galvanostatic pulsed electrodeposition method. These Cu@CuxO nanocatalyst systems exhibit a superior electrochemical CO2 reduction performance when compared to Cu-based catalysts supported on commercial graphene paper or pristine VG without postsynthesis Ar-plasma treatment. The Cu/VG-Ar achieves the highest CO2 reduction Faradaic efficiency of 60.6% (83.5% of which are attributed to liquid products, i.e., formate, ethanol, and n-propanol) with a 5.6 mA cm−2 partial current density at −1.2 V versus reversible hydrogen electrode (RHE). The improved CO2 reduction performance of Cu/VG-Ar originates from the well-dispersed Cu@CuxO nanoparticles deposited on the defective VG-Ar. The intrinsic carbon defects on VG-Ar can suppress the hydrogen evolution reaction as well as tune the interaction between VG and Cu@CuxO, thus impeding the excessive oxidation of Cu2O species deposited on VG-Ar. The defective VG-Ar and stabilized Cu@CuxO enhances CO2 adsorption and promotes electron transfer to the adsorbed CO2 and intermediates on the catalyst surface, thus improving the overall CO2 reduction performance.
KW - Ar plasma treatment
KW - copper nanoparticles
KW - electrochemical CO reduction
KW - intrinsic carbon defects
KW - vertical graphene
UR - http://www.scopus.com/inward/record.url?scp=85085093329&partnerID=8YFLogxK
U2 - 10.1002/adfm.201910118
DO - 10.1002/adfm.201910118
M3 - Article
AN - SCOPUS:85085093329
SN - 1616-301X
VL - 30
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 24
M1 - 1910118
ER -