e/k=5123°K
sigma=2.637 Angström
[T. HALICIOGLU and G. M. POUND: Calculation of Potential Energy Parameters ; phys. stat. sol. (a) 30, 619 (1975) ]
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Lennard-Jones potential:
A = 4εσ6 and B = 4εσ12
Using the continuous approach, where the atoms at discrete locations on the mol- ecule are averaged over a surface, the molecular interatomic energy is obtained by calculating integrals over the surfaces of each molecule, given by
and therefore, E = η1η2(−AI3 + BI6).
The Lennard-Jones parameters for gold nanoparticles are taken from the work
of Pu et al. [Q. Pu, Y. Leng, X. Zhao, P.T. Cummings, Molecular simulations of stretching gold nanowires in solvents. Nanotechnology 18, 424007 (2007)], who use
ε = 0.039kcal mol−1 and σ = 2.934Å
corresponding to A = 7.2465eV ×Å6 and B = 4,622.6273eV ×Å12.
From the fact that gold adopts a face-centred cubic (fcc) crystal structure, the triangular arrangement is employed to determine a mean surface density of gold nanoparticles. Assuming that each atom of gold is coordinated with six other atoms, the area of a unit cell is given by A⋆ = √3d2/2Å2 where d denotes the equilibrium spacing which can be obtained as d = 21/6σ = 3.2933Å. Consequently, the mean surface density η of the gold layers is taken to be 1/A⋆ = 0.1065Å−2.
The Lennard-Jones parameters for gold nanoparticles are taken from the work
of Pu et al. [Q. Pu, Y. Leng, X. Zhao, P.T. Cummings, Molecular simulations of stretching gold nanowires in solvents. Nanotechnology 18, 424007 (2007)], who use
ε = 0.039kcal mol−1 and σ = 2.934Å
corresponding to A = 7.2465eV ×Å6 and B = 4,622.6273eV ×Å12.
From the fact that gold adopts a face-centred cubic (fcc) crystal structure, the triangular arrangement is employed to determine a mean surface density of gold nanoparticles. Assuming that each atom of gold is coordinated with six other atoms, the area of a unit cell is given by A⋆ = √3d2/2Å2 where d denotes the equilibrium spacing which can be obtained as d = 21/6σ = 3.2933Å. Consequently, the mean surface density η of the gold layers is taken to be 1/A⋆ = 0.1065Å−2.
Ref: http://link.springer.com/article/10.1007%2Fs10910-010-9796-x
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