Interatomic interaction at the aluminum-fullerene $\mathrm{C}_{60}$ interface
Abstract
We propose a model describing the interatomic interaction at the interface between fullerene and aluminum. Using the density functional theory, we calculate the binding energy and the fullerene's position on the slab. The obtained data are applied to estimate the parameters of the Lennard-Jones potential for carbon and aluminum atoms, which is then used in molecular dynamics simulations. The results of the theoretical study of desorption of fullerenes from an aluminum substrate are in good agreement with those of the experiments from the literature. We also investigate the capillary effects in an aluminum melt with submerged fullerenes. The positive interface surface energy indicates the poor wettability of by the melt. The calculated value of the diffusion relaxation time is approximately two orders of magnitude less than the characteristic coagulation time of fullerenes. The activation character of the coagulation process and the capillary nature of the interaction between fullerenes are discussed.
Cite
@article{arxiv.2106.08643,
title = {Interatomic interaction at the aluminum-fullerene $\mathrm{C}_{60}$ interface},
author = {V. V. Reshetniak and O. B. Reshetniak and A. V. Aborkin and A. V. Filippov},
journal= {arXiv preprint arXiv:2106.08643},
year = {2024}
}
Comments
15 pages, 9 figures