Atomistic-scale simulations on graphene bending near a copper surface

Malgorzata Kowalik; Md Jamil Hossain; Aditya Lele; Wenbo Zhu; Riju Banerjee; Tomotaroh Granzier-Nakajima; Mauricio Terrones; Eric W. Hudson; Adri C.T. van Duin

doi:10.3390/catal11020208

Atomistic-scale simulations on graphene bending near a copper surface

Malgorzata Kowalik, Md Jamil Hossain, Aditya Lele, Wenbo Zhu, Riju Banerjee, Tomotaroh Granzier-Nakajima, Mauricio Terrones, Eric W. Hudson, Adri C.T. van Duin

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10 Scopus citations

Abstract

Molecular insights into graphene-catalyst surface interactions can provide useful information for the efficient design of copper current collectors with graphitic anode interfaces. As graphene bending can affect the local electron density, it should reflect its local reactivity as well. Using ReaxFF reactive molecular simulations, we have investigated the possible bending of graphene in vacuum and near copper surfaces. We describe the energy cost for graphene bending and the binding energy with hydrogen and copper with two different ReaxFF parameter sets, demonstrating the relevance of using the more recently developed ReaxFF parameter sets for graphene properties. Moreover, the draping angle at copper step edges obtained from our atomistic simulations is in good agreement with the draping angle determined from experimental measurements, thus validating the ReaxFF results.

Original language	English (US)
Article number	208
Pages (from-to)	1-12
Number of pages	12
Journal	Catalysts
Volume	11
Issue number	2
DOIs	https://doi.org/10.3390/catal11020208
State	Published - Feb 2021

All Science Journal Classification (ASJC) codes

Catalysis
General Environmental Science
Physical and Theoretical Chemistry

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10.3390/catal11020208

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title = "Atomistic-scale simulations on graphene bending near a copper surface",

abstract = "Molecular insights into graphene-catalyst surface interactions can provide useful information for the efficient design of copper current collectors with graphitic anode interfaces. As graphene bending can affect the local electron density, it should reflect its local reactivity as well. Using ReaxFF reactive molecular simulations, we have investigated the possible bending of graphene in vacuum and near copper surfaces. We describe the energy cost for graphene bending and the binding energy with hydrogen and copper with two different ReaxFF parameter sets, demonstrating the relevance of using the more recently developed ReaxFF parameter sets for graphene properties. Moreover, the draping angle at copper step edges obtained from our atomistic simulations is in good agreement with the draping angle determined from experimental measurements, thus validating the ReaxFF results.",

author = "Malgorzata Kowalik and Hossain, {Md Jamil} and Aditya Lele and Wenbo Zhu and Riju Banerjee and Tomotaroh Granzier-Nakajima and Mauricio Terrones and Hudson, {Eric W.} and {van Duin}, {Adri C.T.}",

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T1 - Atomistic-scale simulations on graphene bending near a copper surface

AU - Kowalik, Malgorzata

AU - Hossain, Md Jamil

AU - Lele, Aditya

AU - Zhu, Wenbo

AU - Banerjee, Riju

AU - Granzier-Nakajima, Tomotaroh

AU - Terrones, Mauricio

AU - Hudson, Eric W.

AU - van Duin, Adri C.T.

PY - 2021/2

Y1 - 2021/2

N2 - Molecular insights into graphene-catalyst surface interactions can provide useful information for the efficient design of copper current collectors with graphitic anode interfaces. As graphene bending can affect the local electron density, it should reflect its local reactivity as well. Using ReaxFF reactive molecular simulations, we have investigated the possible bending of graphene in vacuum and near copper surfaces. We describe the energy cost for graphene bending and the binding energy with hydrogen and copper with two different ReaxFF parameter sets, demonstrating the relevance of using the more recently developed ReaxFF parameter sets for graphene properties. Moreover, the draping angle at copper step edges obtained from our atomistic simulations is in good agreement with the draping angle determined from experimental measurements, thus validating the ReaxFF results.

AB - Molecular insights into graphene-catalyst surface interactions can provide useful information for the efficient design of copper current collectors with graphitic anode interfaces. As graphene bending can affect the local electron density, it should reflect its local reactivity as well. Using ReaxFF reactive molecular simulations, we have investigated the possible bending of graphene in vacuum and near copper surfaces. We describe the energy cost for graphene bending and the binding energy with hydrogen and copper with two different ReaxFF parameter sets, demonstrating the relevance of using the more recently developed ReaxFF parameter sets for graphene properties. Moreover, the draping angle at copper step edges obtained from our atomistic simulations is in good agreement with the draping angle determined from experimental measurements, thus validating the ReaxFF results.

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Atomistic-scale simulations on graphene bending near a copper surface

Abstract

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