Understanding the molecular forces that drive a reaction or scattering process lies at the heart of molecular dynamics. Here, we present a combined experimental and theoretical study of the spin-orbit...
The
collision geometry, that is, the relative orientation of reactants
before interaction, can have a large effect on how a collision or
reaction proceeds. Certain geometries may prevent access to a given
product channel, while others might enhance it. In this Letter, we
demonstrate how the initial orientation of NO molecules relative to
approaching Ar atoms determines the branching between the spin–orbit
changing and the spin–orbit conserving rotational product channels.
We use a recently developed quantum treatment to calculate differential
and integral branching fractions, at any arbitrary orientation, from
theoretical and experimental data points. Our results show that a
substantial degree of control over the final spin–orbit state
of the scattering products can be achieved by tuning the initial collision
geometry.
Building on our previous work on NO + Ar, this paper presents a complete set of orientation measurements and quantum mechanical calculations for the NO + Kr collision system, including both spin-orbit conserving and changing collisions, and both side-on (x-axis) and end-on (z-axis) orientations. While many of the trends observed in the oriented differential and integral scattering distributions, as well as in the spin-orbit branching fractions, are similar to the ones seen previously for NO + Ar, a direct comparison with the Ar data reveals subtle differences in the scattering dynamics, which we rationalise with the more extended attractive regions on the NO + Kr potential energy surfaces. High-impact parameter collisions that lead to low scattering angles in the spin-orbit conserving manifold are particularly sensitive to the topology in the attractive parts of the potential, whereas more impulsive, low-impact parameter trajectories, which sample the repulsive parts of the potential, produce very similar features in the oriented differential cross sections for the Ar and Kr systems, especially for spin-orbit changing collisions.
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