0 a form of carbon consisting of sheets that have the thickness of one atom. The atoms are arranged in a honeycomb pattern (= a pattern of shapes with six sides).
It was found that hydrogen does not destroy the graphene at these energies, but is instead absorbed or reflected by the graphene.
After repeated bouncing between graphene layers, the incident atom is trapped.
It is seen that the interstitial does not diffuse across the graphene layer.
Incidence at the lowest energies is shown to distort the graphene structure.
The hydrogen adsorption rate is found to be dependent on the incident hydrogen energy and not on graphene temperature.
The rate of hydrogen adsorption was shown to be dependent on the incident energy and not on the graphene temperature.
The carbon wall is treated as graphene layers which are a minimal structure of both a graphite and a carbon fiber.
In both cases curved graphene sheets can be observed together with onion-like particles and defective structures which we have defined fullerene-like structures.