Add to ORKGIn this paper, we construct a continuum model for graphene oxide based upon the Lerf-Klinowski structure to investigate the interaction forces between sheets of graphene oxide. We use the Lennard-Jones potential and coulombic potential to determine the total potential energy between sheets of graphene oxide. We analytically calculate the interaction forces within the system using sums of hypergeometric functions. Our model is then modified to investigate different levels of hydration and oxidation within the system. Our investigations are reconstructed using the LAMMPS molecular dynamics simulator and we find that the analytical solution quickly and effectively calculates results that match well against our simulation data and values taken ...
International audienceWe report the calculation of the solid-liquid interface tension of the graphen...
Based on the density function theory (DFT) method, the interaction between the graphene and oxygen a...
ABSTRACT: We characterize the wetting properties of graphene oxide by performing classical molecular...
In this Letter, the authors invéstigate the interaction of various atoms/ions with a graphene sheet ...
Graphitic nanomaterials have been some of the most widely studied materials of the last decade. The ...
Transport in graphene is strongly limited by the electron-phonon interaction. Accurate description o...
The article investigates the dynamic processes of graphene and the hydrogen atom on the basis of com...
Graphene oxide is a two dimensional material obtained by adsorption of oxygen or oxygen-containing g...
Novel 2D materials, e.g., graphene oxide (GO), are attractive building blocks in the design of advan...
In the present contribution we address the modeling of graphene membranes using a hierarchical model...
The atomic behavior of epoxy groups on a graphene oxide sheet was observed during high thermal heat ...
The interaction between graphene layers is analyzed combining local orbital DFT and second order pe...
The aim of this work is to investigate polymer··· substrate interactions for a polymer nanocomposite...
We present a comparative experimental and molecular-dynamics (MD) simulation study to elucidate the ...
© 2019 American Chemical Society. The graphene oxide (GO)-water interface was simulated using Born-O...
International audienceWe report the calculation of the solid-liquid interface tension of the graphen...
Based on the density function theory (DFT) method, the interaction between the graphene and oxygen a...
ABSTRACT: We characterize the wetting properties of graphene oxide by performing classical molecular...
In this Letter, the authors invéstigate the interaction of various atoms/ions with a graphene sheet ...
Graphitic nanomaterials have been some of the most widely studied materials of the last decade. The ...
Transport in graphene is strongly limited by the electron-phonon interaction. Accurate description o...
The article investigates the dynamic processes of graphene and the hydrogen atom on the basis of com...
Graphene oxide is a two dimensional material obtained by adsorption of oxygen or oxygen-containing g...
Novel 2D materials, e.g., graphene oxide (GO), are attractive building blocks in the design of advan...
In the present contribution we address the modeling of graphene membranes using a hierarchical model...
The atomic behavior of epoxy groups on a graphene oxide sheet was observed during high thermal heat ...
The interaction between graphene layers is analyzed combining local orbital DFT and second order pe...
The aim of this work is to investigate polymer··· substrate interactions for a polymer nanocomposite...
We present a comparative experimental and molecular-dynamics (MD) simulation study to elucidate the ...
© 2019 American Chemical Society. The graphene oxide (GO)-water interface was simulated using Born-O...
International audienceWe report the calculation of the solid-liquid interface tension of the graphen...
Based on the density function theory (DFT) method, the interaction between the graphene and oxygen a...
ABSTRACT: We characterize the wetting properties of graphene oxide by performing classical molecular...