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The combination of time-dependent UV, infra-red, X-ray and visual fluorescence spectroscopy produces a detailed picture of the dynamics of the structural changes on a timescale of pico- to nanoseconds (trillionths to billionths of a second). “We are now able for the first time to understand how pre-distorted states favour charge transfer,” explains Rübhausen. “Also, our studies demonstrate that pre-distorted states are important for photochemical reactions, in other words for certain biochemical processes which are triggered by light,” explains Herres-Pawlis.
The study shows in detail how the process proceeds: from the initial state (copper in an oxidation state of +1) an electron is transferred from the copper to one of the ligands, by optical excitation. Within femtoseconds (trillionths of a second) the excited state created decays into another, still excited state, known as the S1 state. In this configuration, the geometry is slightly relaxed.
Shortly afterwards, the electron undergoes a change in spin. The spin of an electron is comparable to the direction in which a top rotates. Although one of the electrons has so far remained on the ligand, this electron and its corresponding partner on the copper were spin-coupled. The spin of the electron on the ligand now reverses, and this very rapid transition to the so-called triplet state, within just about two picoseconds, removes the spin coupling. This T1 state exists for 120 picoseconds and drops back into the original state again after once again reversing its spin. All the time constants are distinctly shorter compared with other copper complexes. “A complete understanding of all the processes taking place has only become possible through the unique combination of different methods of study,” emphasises Zinth.
Jakob Andreasson, leader of the research Programme for Applications in Molecular, Bio-Medical and Material science at the ELI Beamlines facility in the Czech Republic notes that the present results took several years to obtain, partly for the reason that experiments had to be performed at several different facilities and labs. This is clear evidence, Andreasson says, that we are on the right track at ELI Beamlines where we develop capabilities to do this type of complex research, including combinations of advanced optical and X-ray techniques, in one and the same location and offer them to an international user community.
The detailed analysis of the reaction principle not only improves our understanding of natural processes. It can also help to customise new bioinorganic complexes that imitate nature but whose range of reactions extend beyond those of natural molecules. These complexes could also accelerate or make possible chemical reactions associated with electron transfers in other areas, too.
Scientists from the University of Hamburg, RWTH Aachen University, the Ludwig Maximilian University in Munich, DESY, the University of Paderborn, the European research facility ELI Beamlines, the Institute of Physics of the Czech Academy of Sciences, the University of Uppsala, the Chalmers University of Technology, Göteborg, European XFEL and the Danish Technical University were all involved in the research. The study received grants from Deutsche Forschungsgemeinschaft as part of the dislocated research group FOR1405 (Dynamics of Electron Transfer Processes within Transition Metal Sites in Biological and Bioinorganic Systems) and the SFB749 (Dynamics and Intermediates of Molecular Transformations) and the cluster of excellence CIPSM.
Reference:
Transferring the entatic state principle into copper photochemistry; B. Dicke, A. Hoffmann, J. Stanek, M. S. Rampp, B. Grimm-Lebsanft, F. Biebl, D. Rukser, B. Maerz, D. Göries, M. Naumova, M. Biednov, G. Neuber, A. Wetzel, S. M. Hofmann, P. Roedig, A. Meents, J. Bielecki, J. Andreasson, K. Beyerlein, H. N. Chapman, C. Bressler, W. Zinth, M. Rübhausen and S. Herres-Pawlis; Nature Chemistry, 2017; DOI: 10.1038/nchem.2916.
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