Towards achieving the main goals of AMO-dance we have pursued the following strategies:
1)We have developed a new non-empirical functional beyond the adiabatic approximation by parametrising the memory-dependence part of the xc-functional. We have first identified the relevant terms from an exact analytical relation and then obtained the corresponding coefficients from an ensemble of numerically exact solutions of the TDSE for the same system.
2)We have implemented the developed functional to study Rabi oscillations using resonance on off-resonance laser fields and showed that the results are in a vey good agreement with the numerically exact solution of the TDSE that is available for the system we studied. I n particular, we have shown that our developed functional fulfils the recently developed exact condition for xc kernel, namely it fixes the problem of the spurious time-dependent resonances for adiabatic xc functionals.
3)Based on the Exact Factorization framework in its direct and reverse form we have developed an algorithm to calculate the exact potentials of the KS equations in Multi-Component TDDFT (MC-TDDFT).
We have investigated the KS potentials for two very important problems: the strong-field ionization of molecular systems and the correlated electron-photon states of cavity-QED.
We have accomplished all the deliverables we envisaged in the proposal. The results have been partially published and are accessible on the arXiv (
https://arxiv.org/(se abrirá en una nueva ventana)) repository. There are at least two more papers in preparation to complete the dissemination of the project.
The AMO-dance xc kernel is of huge importance for the community of quantum dynamics and can be used to study a wide range of problems. It is indeed an step beyond the state-of the-art. The outcome of the investigations of the exact KS potentials of MC-TDDFT are the first important steps towards developing reliable approximations on the one hand. On the other hand, for instance the CREI study that is based on an exact time-dependent potential offers an alternative and powerful tool for interpretation of strong-field ionization of the molecules and sets a firm ground to extend the AMO-dance method to study the strong-field dynamics of molecules. Furthermore, the results of the correlated electron-photon states are an important step towards developing accurate xc functional for the emerging fields of cavity-QED chemistry established by the host supervisor. The QED step was conducted beyond what was proposed in the original AMO-dance project.