Studying structure and dynamics on an atomic scale is indispensable for a deeper understanding of several processes in physics, chemistry and biology. Due to their short wavelength x-rays are ideally suited to gain structural information. The natural time scale of atomic motion is the femtosecond region (1 fs = 10-15) not accessible with conventional x-ray sources. In the last few years we have witnessed a tremendous progress in laser technology. Nowadays, ultrashort pulses from compact table top laser systems can be converted in x-ray pulses by nonlinear interactions. With high harmonic generation ultrashort laser pulses at 800 nm have been converted into spatially coherent soft x-ray pulses down to 3 nm. The major objectives of this project are the set up of a soft x-ray source based on high harmonic generation, and he demonstration of its feasability for time resolved x-ray spectroscopy. With soft x-ray radiation ultrafast time-resolved experiments are now feasible, in which the atomic motion in molecular systems can not only be studied in real-time but also be controlled on that time scale. This of course also allows to spatially characterize complex molecules in the liquid phase. Time-resolved soft x-ray diffraction opens up a wide range of new condensed phase studies such as for instance structural changes of photoexcited molecules in chemical reactions, energy transfer in electron-photon surface interactions, details of acoustic and optical phonon dynamics. Adaptive shaping of phase, amplitude and polarization state of femtosecond laser pulses is a new tool to control complex dynamics (phonon modes, chemical reactions) in the condensed phase. This recently developed technique is expected to have a major impact in the broad applications of ultrafast soft x-ray spectroscopy.

DFG-Verfahren Schwerpunktprogramme

Teilprojekt zu SPP 1134:  Aufklärung transienter Strukturen in kondensierter Materie mit Ultrakurzzeit-Röntgenmethoden