The closed-edge structure of graphite and the effect of electrostatic charging

Victor Posligua; Joana Bustamante; Cesar H. Zambrano; Peter J.F. Harris; Ricardo Grau-Crespo

doi:10.1039/c9ra09913a

The closed-edge structure of graphite and the effect of electrostatic charging

Victor Posligua
, Joana Bustamante
, Cesar H. Zambrano
, Peter J.F. Harris
, Ricardo Grau-Crespo^*

^*Corresponding author for this work

University of Reading
Universidad Técnica Particular de Loja

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

The properties of graphite, and of few-layer graphene, can be strongly influenced by the edge structure of the graphene planes, but there is still much that we do not understand about the geometry and stability of these edges. We present an experimental and theoretical study of the closed edges of graphite crystals, and of the effect of an electric field on their structure. High-resolution transmission electron microscopy is used to image the edge structure of fresh graphite and of graphite that has been exposed to an electric field, which experiences a separation of the graphene layers. Computer simulations based on density functional theory are used to rationalise and quantify the preference for the formation of multiple concentric loops at the edges. A model is also presented to explain how the application of an electric field leads to the separation of the folded edges.

Original language	English
Pages (from-to)	7994-8001
Number of pages	8
Journal	RSC Advances
Volume	10
Issue number	13
DOIs	https://doi.org/10.1039/c9ra09913a
State	Published - 24 Feb 2020

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10.1039/c9ra09913a

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abstract = "The properties of graphite, and of few-layer graphene, can be strongly influenced by the edge structure of the graphene planes, but there is still much that we do not understand about the geometry and stability of these edges. We present an experimental and theoretical study of the closed edges of graphite crystals, and of the effect of an electric field on their structure. High-resolution transmission electron microscopy is used to image the edge structure of fresh graphite and of graphite that has been exposed to an electric field, which experiences a separation of the graphene layers. Computer simulations based on density functional theory are used to rationalise and quantify the preference for the formation of multiple concentric loops at the edges. A model is also presented to explain how the application of an electric field leads to the separation of the folded edges.",

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AU - Bustamante, Joana

AU - Zambrano, Cesar H.

AU - Harris, Peter J.F.

AU - Grau-Crespo, Ricardo

PY - 2020/2/24

Y1 - 2020/2/24

N2 - The properties of graphite, and of few-layer graphene, can be strongly influenced by the edge structure of the graphene planes, but there is still much that we do not understand about the geometry and stability of these edges. We present an experimental and theoretical study of the closed edges of graphite crystals, and of the effect of an electric field on their structure. High-resolution transmission electron microscopy is used to image the edge structure of fresh graphite and of graphite that has been exposed to an electric field, which experiences a separation of the graphene layers. Computer simulations based on density functional theory are used to rationalise and quantify the preference for the formation of multiple concentric loops at the edges. A model is also presented to explain how the application of an electric field leads to the separation of the folded edges.

AB - The properties of graphite, and of few-layer graphene, can be strongly influenced by the edge structure of the graphene planes, but there is still much that we do not understand about the geometry and stability of these edges. We present an experimental and theoretical study of the closed edges of graphite crystals, and of the effect of an electric field on their structure. High-resolution transmission electron microscopy is used to image the edge structure of fresh graphite and of graphite that has been exposed to an electric field, which experiences a separation of the graphene layers. Computer simulations based on density functional theory are used to rationalise and quantify the preference for the formation of multiple concentric loops at the edges. A model is also presented to explain how the application of an electric field leads to the separation of the folded edges.

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The closed-edge structure of graphite and the effect of electrostatic charging

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