Non-adiabatic transitions and quantum mechanical tunneling of protons are important processes in chemical and biochemical systems. The description of such processes in complex systems using non-adiabatic quantum dynamics methods is the aim of this project. In the last decade the ring-polymer molecular dynamics (RPMD) approach has shown to be a useful tool for approximate quantum dynamics simulations. Non-adiabatic processes cannot be described using the RPMD approach directly, but an extension of the RPMD approach to simulate two-state non-adiabatic processes, the kinetically constrained (KC) RPMD, was proposed very recently. The project aims to generalize and further develop the KC-RPMD approach. Furthermore, the approach will be used to investigate chemically and biochemically important non-adiabatic processes in complex systems. Several bioinorganic systems showing electron transfer processes (ET) or proton coupled electron transfer processes (PCET) can be considered: complexes based on Bis(imidazole) Iron Tetraphenylporphyrins, azurin proteins, a tris(phosphine)borane-supported iron complex, iron complexes with tris(phosphino)alkyl ligands featuring an axial carbon donor, cobalt complexes with diglyoxime ligands.

DFG Programme Research Fellowships

International Connection USA

Host Professor Thomas F. Miller III, Ph.D.