Dataset: Electron-nuclear quantum dynamics of diatomic molecules
收藏Zenodo2025-08-01 更新2026-05-26 收录
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https://zenodo.org/doi/10.5281/zenodo.5069644
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The Born-Oppenheimer approximation is the fundamental approximation in the quantum-mechanical description of molecules, and holds true in most applications for ground-state properties and to a lesser extent for excited states. In situations where the coupling of electronic and nuclear motion becomes significant, for example in strong-field induced time-dependent processes, the electron-nuclear interaction must be described beyond the Born-Oppenheimer picture.
Presented here are multiconfiguration electron-nuclear dynamics simulations with and without a laser pulse excitation for the diatomic molecules H2, HeH+, LiH, BeH+, Li2, and N2, taking into account electron-nuclear coupling. The computational approach allows a direct propagation of the electron-nuclear wave function, thus avoiding the construction of potential energy surfaces.
With this approach, ground-state and time-dependent properties including equilibrium bond lengths, dipole moments, and electronic, vibrational, and high-harmonic spectra are obtained.
For some of the diatomics, manifestations of nonadiabatic effects are observed in the high-harmonic spectra, where both an uptake of nuclear motion and electronic excitation into higher-lying excited states can occur, resulting in an effective driving force that displaces the nuclei from the equilibrium position. Isotope effects can also be observed in electronic excitation spectra.
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2025-08-01



