posted on 2007-04-11, 00:00authored byHervé Lesnard, Marie-Laure Bocquet, Nicolás Lorente
We have performed a theoretical study on the dehydrogenation of benzene and pyridine molecules
on Cu(100) induced by a scanning tunneling microscope (STM). Density functional theory calculations
have been used to characterize benzene, pyridine, and different dehydrogenation products. The adiabatic
pathways for single and double dehydrogenation have been evaluated with the nudge elastic band method.
After identification of the transition states, the analysis of the electronic structure along the reaction pathway
yields interesting information on the electronic process that leads to H-scission. The adiabatic barriers
show that the formation of double dehydrogenated fragments is difficult and probably beyond reach under
the actual experimental conditions. However, nonadiabatic processes cannot be ruled out. Hence, in order
to identify the final dehydrogenation products, the inelastic spectra are simulated and compared with the
experimental ones. We can then assign phenyl (C6H5) and α-pyridil (α-C5H4N) as the STM-induced
dehydrogenation products of benzene and pyridine, respectively. Our simulations permit us to understand
why phenyl, pyridine, and α-pyridil present tunneling-active C−H stretch modes in opposition to benzene.