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Abstract
We have calculated energy barriers of chemical reactions between hydrogen atoms and silane molecules (SiH4 and SiCl4) in the framework of conventional transition-state theory based on density functional theory. By calculating the intrinsic reaction paths it is shown that two internal parameters are sufficient to describe the reactions. Corresponding potential energy surfaces (PES) have been derived for both reactions in terms of these two degrees of freedom. We have also performed molecular dynamics (MD) simulations of scattering processes between hydrogen atoms and silane molecules. Projection of the MD trajectories onto the PES's gives further insight into the underlying reaction mechanisms and reveals a fundamental difference between the two reactions.
Acknowledgements
We acknowledge the support by the Deutsche Forschungsgemeinschaft (SFB 445 “Nanoparticles from the Gas Phase: Formation, Structure, Properties”).