nonadiabatiska

Nonadiabatiska, or nonadiabatic, processes describe situations in which electronic and nuclear motions in a molecule are strongly coupled and cannot be treated as independent. In the Born-Oppenheimer approximation, nuclei move on a single electronic potential energy surface; nonadiabatic dynamics arise when electronic states interact as nuclei change, leading to transitions between surfaces driven by nuclear motion. These effects are especially important when potential energy surfaces come close or cross, creating strong couplings.

Key concepts include potential energy surfaces, derivative (nonadiabatic) couplings, conical intersections, and vibronic interactions. Transitions between

Methods to study nonadiabatiska dynamics combine theory and experiment. On the theory side, approaches such as

Understanding nonadiabatiska dynamics is crucial for photochemistry, photovoltaics, vision chemistry, and catalysis, where controlling excited-state lifetimes