@Article{icces.2023.09484,
AUTHOR = {Xinliang Li, Jiangang Guo},
TITLE = {Uniaxial Compressive Mechanical Properties of Three-Dimensional Graphene: Theoretical Models and Molecular Dynamics Simulations},
JOURNAL = {The International Conference on Computational \& Experimental Engineering and Sciences},
VOLUME = {27},
YEAR = {2023},
NUMBER = {1},
PAGES = {1--2},
URL = {http://www.techscience.com/icces/v27n1/54097},
ISSN = {1933-2815},
ABSTRACT = {As the first two-dimensional (2D) material discovered in experiments, graphene has attracted increasing
attention from the scientific community [1]. And it possesses many superb mechanical, electronic and
optical properties [2-4] due to its unique atomic structure. Its Young’s modulus and failure strength are 1TPa
and 130GPa [5], respectively. Thus, 2D graphene has been extensively used in nanosensors and
nanocomposites [6-8], etc. In order to fabricate graphene-based devices which inherit outstanding
properties of 2D graphene, materials scientists are trying to use 2D graphene as building blocks to construct
three-dimensional (3D) carbon nanomaterials, such as 3D graphene networks [9-11]. Nowadays, these 3D
carbon nanomaterials have become potential candidates which can be integrated into molecular sieves,
supercapacitors and energy absorbing devices [12-14], etc. Therefore, it is important to investigate
compressive mechanical properties and deformation mechanisms of 3D carbon nanomaterials.
Combining molecular dynamics (MD) simulations and continuum modeling, the uniaxial in-plane
compressive properties and deformation mechanisms of honeycomb three-dimensional graphene, trianglelike 3D graphene and non-equilateral hexagon 3D graphene are investigated to elucidate configurationproperty relationships, and the constitutive relations of three kinds of 3D graphene are derived to evaluate
the compressive mechanical properties. Based on theoretical and MD simulation results, it is found that the
compressive stress-strain responses of three types of 3D graphene can be divided into five stages. They are
the linear elastic stage I, the stress plateau stage II, the van der Waals (vdW) hardening stage III, the initial
crushing stage IV and the densification stage V, respectively. The compressive mechanical properties and
deformation mechanisms of each stage are different.
In the linear elastic stage I, the stress increases linearly with increasing strain. Graphene sidewalls of 3D
graphene undergo compressive deformation, bending deformation and rotation. In the stress plateau stage
II, the plateau stress of 3D graphene is almost a constant with increasing the compressive strain. Graphene
sidewalls undergo buckling deformation and rotation. In the vdW hardening stage III, the compressive stress
gradually increases with the increase of strain. The distance between graphene sidewalls gradually
decreases with the increase of compressive strain. And vdW repulsive interaction strength between two
sidewalls gradually increases. In the initial crushing stage IV, as increasing the compressive strain, the stress
increases exponentially. And the crushing region of graphene sidewalls gradually extends to the whole 3D
graphene structure. In the densification stage V, the stress increases sharply with the increase of
compressive strain. And 3D graphene is completely compacted.
Through analyzing energy absorption mechanisms and compression-unloading stress-strain curves for
three types of 3D graphene, it is found that there are extraordinary compression-recovery properties and
energy absorption capacities in 3D graphene. Besides, the Young's modulus, plateau stress and locking strain
of 3D graphene gradually decrease with increasing graphene sidewall width.},
DOI = {10.32604/icces.2023.09484}
}