We review the state-of-the art in dynamics calculations on the reactive scattering of H2 from
metal surfaces, which is an important model system of an elementary reaction that is …

Great success has been achieved in the modeling of gas-surface elementary processes by
the use of the Born-Oppenheimer approximation. However, in metal surfaces low energy …

We review the state-of-the-art in the theory of dissociative chemisorption (DC) of small gas
phase molecules on metal surfaces, which is important to modeling heterogeneous catalysis …

We review studies of molecular interactions and chemical reactions at metal surfaces,
emphasizing progress toward a predictive theory of surface chemistry and catalysis. For …

At present, molecular dynamics with electronic friction (MDEF) is the workhorse model to go
beyond the Born–Oppenheimer approximation in modeling dynamics of molecules at metal …

Conversion of energy at the gas–solid interface lies at the heart of many industrial
applications such as heterogeneous catalysis. Dissipation of parts of this energy into the …

The influence of electron–hole pairs in dissociative chemisorption of a polyatomic molecule
(water) on metal surfaces is assessed for the first time using a friction approach. The atomic …

Ab initio molecular dynamics with electronic friction (AIMDEF) is a valuable methodology to
study the interaction of atomic particles with metal surfaces. This method, in which the effect …

Energy transfer is ubiquitous during molecular collisions and reactions at gas–surface
interfaces. Of particular importance is vibrational energy transfer because of its relevance to …

The breakdown of the Born–Oppenheimer approximation gives rise to nonadiabatic effects
in gas-surface reactions at metal surfaces. However, for a given reaction, it remains unclear …