Yupeng Huang scite author profile

Theoretical calculations reveal that intrinsic pentagons in the basal plane can contribute to the local electronic redistribution and the contraction of band gap, making the carbon matrix possess superior binding affinity and electrochemical reactivity. To experimentally verify this, a pentagon‐defect‐rich carbon nanomaterial was constructed by means of in situ etching of fullerene molecules (C60). The electrochemical tests show that, relative to hexagons, such a carbon‐based material with abundant intrinsic pentagon defects makes much greater contribution to the electrocatalytic oxygen reduction activity and electric double layer capacitance. It shows a four‐electron‐reaction mechanism similar to commercial Pt/C and other transition‐metal‐based catalysts, and a higher specific capacitance than many reported metal‐free carbon materials. These results show the influence of intrinsic pentagon defects for developing carbon‐based nanomaterials toward energy conversion and storage devices.

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Effects of Intrinsic Pentagon Defects on Electrochemical Reactivity of Carbon Nanomaterials

Zhu

Huang

Zhao

et al. 2019

Angewandte Chemie

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Theoretical calculations reveal that intrinsic pentagons in the basal plane can contribute to the local electronic redistribution and the contraction of band gap,m aking the carbon matrix possess superior binding affinity and electrochemical reactivity.T oe xperimentally verify this,apentagondefect-richc arbon nanomaterial was constructed by means of in situ etching of fullerene molecules (C 60 ). The electrochemical tests showt hat, relative to hexagons,s uch ac arbon-based material with abundant intrinsic pentagon defects makes much greater contribution to the electrocatalytic oxygen reduction activity and electric double layer capacitance.Itshows afourelectron-reaction mechanism similar to commercial Pt/C and other transition-metal-based catalysts,a nd ah igher specific capacitance than many reported metal-free carbon materials. These results showt he influence of intrinsic pentagon defects for developing carbon-based nanomaterials toward energy conversion and storage devices.

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Yupeng Huang

Effects of Intrinsic Pentagon Defects on Electrochemical Reactivity of Carbon Nanomaterials

Effects of Intrinsic Pentagon Defects on Electrochemical Reactivity of Carbon Nanomaterials

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