Methylene
(CH<sub>2</sub>) is thought to play a significant role
as a reaction intermediate in the catalysis of methane dry reforming
as well as in converting synthesis gas to light olefins via Fischer–Tropsch
synthesis. Here, we report high quality Born–Oppenheimer molecular
dynamics (BOMD) simulations of the reaction mechanisms associated
with CH<sub>2</sub> impinging on a Ni(110) surface with CO<sub>2</sub> adsorbed at 0.33 ML coverage. The results show the formation of
formaldehyde, carbon monoxide, C<sub>2</sub> species such as H<sub>2</sub>C–CO<sub>2</sub>, and others. Furthermore, we provide
real-time demonstration of both Eley–Rideal (ER) and hot atom
(HA) reaction mechanisms. The ER mechanism mostly happens when CH<sub>2</sub> directly collides with an oxygen of CO<sub>2</sub>, while
CH<sub>2</sub> attacks the carbon of CO<sub>2</sub>, dominantly following
the HA mechanism. If CH<sub>2</sub> reaches the Ni surface, it can
easily break one C–H bond to form CH and H on the surface.
The mechanistic details of H<sub>2</sub>CO, H/CO, C<sub>2</sub>, and
H/CH formation are illuminated through the study of bond breaking/formation,
charge transfer, and spin density of the reactants and catalytic surface.
This illuminates the key contribution of geometry and electronic structure
of catalytic surface to the reaction selectivity. Moreover, we find
that <sup>3</sup>CH<sub>2</sub> switches to surfaces of <sup>1</sup>CH<sub>2</sub> character as soon as the methylene and nickel/CO<sub>2</sub> orbitals show significant interaction, and as a result the
reactivity is dominated by low barrier mechanisms. Overall, the BOMD
simulations provide dynamical information that allows us to monitor
details of the reaction mechanisms, confirming and extending current
understanding of CH<sub>2</sub> radical chemistry in the dry reforming
of methane and Fischer–Tropsch synthesis