Workshops General Archive
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The study of nuclei far from stability is one of the most active domains in nuclear physics today. In particular, the advent in recent years of facilities such as the RIKEN Radioactive Ion Beam Factory has provided a step change in our ability to study the most exotic systems.More info
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The workshop will be devoted to the study of the nucleon resonance spectrum and structure as it becomes accessible through the electromagnetic excitation of the nucleon (EmNN*) in exclusive meson production.More info
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Excited-State Quantum Phase Transition (ESQPT) is a novel concept unifying various types of singularities present in discrete energy spectra of quantum systems with a limited number of effective degrees of freedom.More info
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Various heavy ion accelerators are under construction, including FAIR and RAON. A deep understanding of rare isotope physics is essential for a microscopically founded modelling of the astrophysical problems related to dense matter in the universe, as it can be found in neutron stars and black holes.More info
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This workshop will explore the impact of QCD effects on the choice of future high energy accelerators, where to pursue effective studies of the BEH (Brout-Englert-Higgs) boson in view of ascertaining its true nature.More info
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This Humboldt Kolleg will bring together key experimenters and theorists in the physics of low-energy nuclear science to debate recent achievements and discuss in depth new perspectives for further progress in the understanding of the properties and production mechanisms of the heaviest nuclei.More info
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The number and quality of laser spectroscopy studies on short-lived nuclei to explore changes in the nuclear size, spin, and moments for isotopes far away from stability, has increased tremendously in the last decade.More info
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The HAdron SPEctroscopy CenTer (HASPECT) brings together theorists and experimentalists with goal to develop the necessary tools for the future analysis in hadron physics.More info
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The strong interaction between nucleons results from quantum chromodynamics (QCD). With the ability to solve QCD on the lattice for the lightest nuclei, it will be possible to derive the nuclear systematics from few fundamental constants.More info