posted on 2023-09-23, 12:03authored byZhiguo Zhang, Hao Wu, Zhichao Chen, Yanlin Fu, Bina Fu, Dong H. Zhang, Xueming Yang, Kaijun Yuan
The exquisite features
of molecular photochemistry are key to any
complete understanding of the chemical processes governed by potential
energy surfaces (PESs). It is well established that multiple dissociation
pathways relate to nonadiabatic transitions between multiple coupled
PESs. However, little detail is known about how the single PES determines
reaction outcomes. Here we perform detailed experiments on HNCO photodissociation,
acquiring the state-specific correlations of the NH (a1Δ) and CO (X1Σ+) products. The experiments reveal a trimodal CO rotational
distribution. Dynamics simulations based on a full-dimensional machine-learning-based
PES of HNCO unveil three dissociation pathways exclusively occurring
on the S1 excited electronic state. One
pathway, following the minimum energy path (MEP) via the transition
state, contributes to mild rotational excitation in CO, while the
other two pathways deviating substantially from the MEP account for
relatively cold and hot CO rotational state populations. These peculiar
dynamics are unambiguously governed by the S1 state PES topography, i.e., a narrow acceptance cone in the
vicinity of the transition state region. The dynamical picture shown
in this work will serve as a textbook example illustrating the importance
of the PES topography in molecular photochemistry.