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Chiral-Dependent Tensile Mechanics of Graphene

We report a molecular dynamics study on the tensile mechanics of graphene as gradually rotating the tensile direction from armchair to zigzag direction, covering the complete range of chiral directions which has never been explored so far. We observed monotonic increases of tensile strength and strain as the chiral (rotational) angle increases. Key feature is their negligible changes up to chiral angle of ~12° and the subsequent rapid increases and this pattern holds for all temperatures examined here (100-700 K). Considering a topologically consistent (zigzag-lines) breaking of graphene, we presented a unified fracture model that successfully reproduced the simulation results as well as explaining their physical origin. Notably, we found that the elastic stress of graphene is quasi-isotropic for all chiral directions in contrast to its anisotropic fracture behavior. Through the indentation simulations of graphene, we demonstrated that our rationale established in uniaxial (1D) tensile systems is applicable to 2D tensile systems as well.

preprint2013arXivOpen access
Young In JhonMyung S. Jhon
cond-mat.mes-hallcond-mat.mtrl-sci
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Young In JhonMyung S. Jhon

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