Add to ORKGTwo-dimensional (2D) layers like graphene are subject to long-wavelength fluctuations that manifest themselves as strong height fluctuations (ripples). In order to control the ripples, their relationship with external strain needs to be established. We therefore perform molecular dynamics (MD) of suspended graphene, by the use of a newly developed force field model (MMP) that we prove to be extremely accurate for both C Diamond and Graphene. The MMP potential successfully reproduces the energy of the r-bonds in both sp3 and sp2 configuration. Our MD simulations and experimental electron microscopy analysis reveal that ordered and static ripples form spontaneously as a direct response to external pressure. Furthermore the morphology of graph...
We explore here the structural stability and fracture of supported graphene sheets under pressure lo...
Molecular dynamics simulations based on many-body interatomic potentials are conducted to investigat...
ABSTRACT: We investigate the organized formation of strain, ripples, and suspended features in macro...
AbstractTwo-dimensional (2D) layers like graphene are subject to long-wavelength fluctuations that m...
peer-reviewedTwo-dimensional (2D) layers like graphene are subject to long-wavelength fluctuations t...
Recent advances in the understanding of graphene elasticity have shown that suspended graphene does ...
The effect of intrinsic ripples on the mechanical response of the graphene monolayer is investigated...
We study the dispersion characteristics of strained graphene using many-body interatomic potentials ...
There is a growing interest in the strain engineering of 2D materials for applications in semiconduc...
An isotropic compression of graphene is shown to induce a structural deformation on the basis of Den...
Several aspects of the mechanical behavior of single-layer graphene are modeled from perspectives ra...
Graphene is a one atom thick layer of carbon atoms arranged in hexagonal lattice in two-dimensions. ...
Molecular dynamics is employed to study the mechanical behavior of graphene nanoribbons with clamped...
Graphene is a single atomic sheet of graphite that exhibits a diverse range of unique properties. Th...
This thesis concerns describing the mechanical properties of the two dimensional material graphene b...
We explore here the structural stability and fracture of supported graphene sheets under pressure lo...
Molecular dynamics simulations based on many-body interatomic potentials are conducted to investigat...
ABSTRACT: We investigate the organized formation of strain, ripples, and suspended features in macro...
AbstractTwo-dimensional (2D) layers like graphene are subject to long-wavelength fluctuations that m...
peer-reviewedTwo-dimensional (2D) layers like graphene are subject to long-wavelength fluctuations t...
Recent advances in the understanding of graphene elasticity have shown that suspended graphene does ...
The effect of intrinsic ripples on the mechanical response of the graphene monolayer is investigated...
We study the dispersion characteristics of strained graphene using many-body interatomic potentials ...
There is a growing interest in the strain engineering of 2D materials for applications in semiconduc...
An isotropic compression of graphene is shown to induce a structural deformation on the basis of Den...
Several aspects of the mechanical behavior of single-layer graphene are modeled from perspectives ra...
Graphene is a one atom thick layer of carbon atoms arranged in hexagonal lattice in two-dimensions. ...
Molecular dynamics is employed to study the mechanical behavior of graphene nanoribbons with clamped...
Graphene is a single atomic sheet of graphite that exhibits a diverse range of unique properties. Th...
This thesis concerns describing the mechanical properties of the two dimensional material graphene b...
We explore here the structural stability and fracture of supported graphene sheets under pressure lo...
Molecular dynamics simulations based on many-body interatomic potentials are conducted to investigat...
ABSTRACT: We investigate the organized formation of strain, ripples, and suspended features in macro...