A Tailored Bifunctional Electrocatalyst: Boosting Oxygen Reduction/Evolution Catalysis via Electron Transfer Between N-Doped Graphene and Perovskite Oxides.
Yunfei BuGyutae NamSeona KimKeunsu ChoiQin ZhongJunHee LeeYong QinJaephil ChoGuntae KimPublished in: Small (Weinheim an der Bergstrasse, Germany) (2018)
Fabricating perovskite oxide/carbon material composite catalysts is a widely accepted strategy to enhance oxygen reduction reaction/oxygen evolution reaction (ORR and OER) catalytic activities. Herein, synthesized, porous, perovskite-type Sm0.5 Sr0.5 CoO3-δ hollow nanofibers (SSC-HF) are hybridized with cross-linked, 3D, N-doped graphene (3DNG). This rationally designed hybrid catalyst, SSC-HF-3DNG (SSC-HG), exhibits a remarkable enhancement in ORR/OER activity in alkaline media. The synergistic effects between SSC and 3DNG during their ORR and OER processes are firstly revealed by density functional theory calculations. It suggests that electron transport from 3DNG to O2 and SSC increases the activity of electrocatalytic reactions (ORR and OER) by activating O2 , increasing the covalent bonding of lattice oxygen. This electron transfer-accelerated catalysis behavior in SSC-HG will provide design guidelines for composites of perovskite and carbon with bifunctional catalysts.
Keyphrases
- metal organic framework
- electron transfer
- highly efficient
- room temperature
- density functional theory
- high efficiency
- solar cells
- molecular dynamics
- visible light
- reduced graphene oxide
- fluorescent probe
- heart failure
- clinical practice
- cancer therapy
- mass spectrometry
- atrial fibrillation
- carbon nanotubes
- high resolution
- smoking cessation
- molecularly imprinted
- living cells
- transition metal
- walled carbon nanotubes