AI Article Synopsis
- The study focuses on the molecular dynamics of the butatriene cation when it transitions from the ground state to the first excited electronic state using the time-dependent discrete variable representation (TDDVR) method.
- The researchers initially modeled the dynamics with a basic five-mode model, then expanded it to include an additional thirteen modes, analyzing the impact of these weak modes on the energy and population transfer.
- The spectral profiles obtained through the TDDVR method show good agreement with both quantum mechanical calculations and experimental measurements, suggesting that TDDVR is an effective balance of accuracy and efficiency for studying larger systems.
Article Abstract
We are investigating the molecular dynamics of the butatriene cation after excitation from the ground state (X(2)B(2g)) to the first excited electronic state (A(2)B(2u)) by using the time-dependent discrete variable representation (TDDVR) method. The investigation is being carried out with a realistic 18-mode model Hamiltonian consisting of all the vibrational degrees of freedom of the butatriene molecule. First, we perform the simulation on a basic five mode model, and then by including additional thirteen modes as bath on the basic model. This sequential inclusion of bath modes demonstrates the effect of so called weak modes on the subsystem, where the calculations of energy and population transfer from the basic model to the bath quantify the same effect. The spectral profile obtained by using the TDDVR approach shows reasonably good agreement with the results calculated by the quantum mechanical approach/experimental measurement. It appears that the TDDVR approach for those large systems where quantum mechanical description is needed in a restricted region, is a good compromise between accuracy and speed.
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