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Molecular dynamics simulation of perforation of graphene under impact by fullerene projectiles

Yang Zhang, Yun Qiu, Fuzhou Niu, A.S. Ademiloye

2022Materials Today Communications14 citationsDOIOpen Access PDF

Abstract

In this paper, molecular dynamics (MD) simulations are employed to study the perforation of graphene under impact by fullerenes of various sizes. The buckling characteristics of fullerenes after impact are classified and discussed. The relative state of C180 projectile and graphene under impact at different velocities is also investigated. We observed that the C180 projectile rebounds at low velocity (V < 4.25 km/s), sticks to graphene at high velocity (4.25 km/s ≤ V ≤ 4.75 km/s), and perforates the graphene at higher velocity (V ≥ 4.75 km/s). It is found that the buckled cap of large-size fullerene formed after impact can better absorb kinetic energy. In addition, different crack modes of graphene after perforation were investigated. The effect of fullerene projectile size and initial velocity on ballistic limit velocity was also clarified. This study provides new implications for the application of large-size fullerenes as impact shields.

Topics & Concepts

ProjectileFullereneGrapheneMaterials sciencePerforationMolecular dynamicsBallistic limitKinetic energyNanotechnologyComposite materialPhysicsClassical mechanicsQuantum mechanicsMetallurgyPunchingGraphene research and applicationsDiamond and Carbon-based Materials ResearchEnergetic Materials and Combustion
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