The excellent mechanical properties of graphene have enabled it as appealing candidate in the field of impact protection or protective shield. By considering a monolayer graphene membrane, in this work, we assessed its deformation mechanisms under hypervelocity impact (from 2 to 6 km/s), based on a serial of in silico studies. It is found that the cracks are formed preferentially in the zigzag directions which are consistent with that observed from tensile deformation. Specifically, the boundary condition is found to exert an obvious influence on the stress distribution and transmission during the impact process, which eventually influences the penetration energy and crack growth. For similar sample size, the circular shape graphene possesses the best impact resistance, followed by hexagonal graphene membrane. Moreover, it is found the failure shape of graphene membrane has a strong relationship with the initial kinetic energy of the projectile. The higher kinetic energy, the more number the cracks. This study provides a fundamental understanding of the deformation mechanisms of monolayer graphene under impact, which is crucial in order to facilitate their emerging future applications for impact protection, such as protective shield from orbital debris for spacecraft.
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机译:石墨烯的优异机械性能使其成为抗冲击或防护罩领域的理想之选。通过考虑单层石墨烯膜,在这项工作中,我们基于一系列计算机模拟研究,评估了其在超高速冲击(2至6 km / s)下的变形机理。发现裂纹优先在锯齿形方向上形成,这与从拉伸变形观察到的一致。具体来说,发现边界条件对冲击过程中的应力分布和传递有明显的影响,最终影响了穿透能和裂纹扩展。对于相似的样品大小,圆形石墨烯具有最佳的抗冲击性,其次是六角形石墨烯膜。此外,发现石墨烯膜的破坏形状与弹丸的初始动能有很强的关系。动能越高,裂纹数量越多。这项研究提供了对单层石墨烯在冲击下的变形机理的基本理解,这对于促进其在冲击保护中的新兴应用(例如对航天器的轨道碎片的防护)至关重要。
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