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"The role fission reactions play in these processes has not yet been researched in detail. Nucleosynthesis processes such as s-process or r-process take place in exactly such media," explains Boller. "Understanding the reaction processes of nuclei interacting with each other in plasma can give us insights into the origin of atomic nuclei, the so-called nucleosynthesis, in our universe. Comparable conditions can be found, for example, in space inside stars, stellar explosions or neutron star mergers. This provides a methodology for studying fission reactions in high-density plasma-state matter. In this way, generation and measurement can be spatially separated and interference can be prevented.įor the first time, it was possible in the experiments to combine the two techniques and thus to generate a variety of cesium, xenon and iodine isotopes via the fission of uranium, to reliably identify them via their emitted gamma radiation and to observe their short life time. The reaction chamber is flushed through by a gas which-in the case of fission experiments-carries the fission products with it and, within only a few seconds, transports them via small plastic tubes to the measuring apparatus, which is now several meters away. For the chemical investigation of superheavy elements, a transport system has been in use for quite some time that can transport the desired particles over long distances from the reaction area to the detector. However, the laser impact has unwanted side effects: It generates a strong electromagnetic pulse and a gammy-ray flash that interfere with the sensitive measuring instruments used for this detection.Īt this stage, the researchers are assisted by the expertise of another GSI research group. The protons generated by the PHELIX laser are fast enough to induce the fission of uranium nuclei into smaller fission products, which remain then to be identified and measured. The samples have to be close to the proton production to guarantee a maximum yield of reactions. Uranium was chosen as a case study material because of its large reaction cross-section and the availability of published data for benchmarking purposes. For this purpose, the researchers let the freshly generated fast protons impinge on uranium material samples. These include the generation of nuclear fission reactions. "With this technology, completely new research areas can be opened that were previously inaccessible." "Such a large number of protons in such a short period of time cannot be achieved with standard acceleration techniques," explains Pascal Boller, who is researching laser acceleration in the GSI research department Plasma Physics/PHELIX as part of his graduate studies. This is enough to eject about one trillion hydrogen nuclei (protons), which are only slightly attached to the gold, from the back-surface of the foil, and accelerate them to high energies. For less than one picosecond (one trillionth of a second), the PHELIX laser shines its extremely intense light pulse onto a very thin gold foil.