LNM, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, PR China.
Nano Lett. 2013 Jan 9;13(1):26-30. doi: 10.1021/nl303168w. Epub 2012 Dec 7.
Bending rigidity and Gaussian bending stiffness are the two key parameters that govern the rippling of suspended graphene-an unavoidable phenomenon of two-dimensional materials when subject to a thermal or mechanical field. A reliable determination about these two parameters is of significance for both the design and the manipulation of graphene morphology for engineering applications. By combining the density functional theory calculations of energies of fullerenes and single wall carbon nanotubes with the configurational energy of membranes determined by Helfrich Hamiltonian, we have designed a theoretical approach to accurately determine the bending rigidity and Gaussian bending stiffness of single-layered graphene. The bending rigidity and Gaussian bending stiffness of single-layered graphene are 1.44 eV (2.31 × 10(-19) N m) and -1.52 eV (2.43 × 10(-19) N m), respectively. The bending rigidity is close to the experimental result. Interestingly, the bending stiffness of graphene is close to that of lipid bilayers of cells about 1-2 eV, which might mechanically justify biological applications of graphene.
弯曲刚度和高斯弯曲刚度是控制悬浮石墨烯产生波纹的两个关键参数,这是二维材料在热或力场中不可避免的现象。这两个参数的可靠确定对于工程应用中石墨烯形态的设计和操控都具有重要意义。通过将富勒烯和单壁碳纳米管的能量的密度泛函理论计算与赫夫里希哈密顿确定的膜的构型能相结合,我们设计了一种理论方法来精确确定单层石墨烯的弯曲刚度和高斯弯曲刚度。单层石墨烯的弯曲刚度和高斯弯曲刚度分别为 1.44eV(2.31×10^-19N·m)和-1.52eV(2.43×10^-19N·m)。弯曲刚度接近实验结果。有趣的是,石墨烯的弯曲刚度接近细胞脂质双层的 1-2eV,这可能从力学上证明了石墨烯在生物应用中的合理性。
