Theoretical Astro-, Nuclear-, and Particle Physics
Welcome to the homepage of the research groups in theoretical astro-, nuclear-, and particle physics at the Physics Department of the University of Basel, Switzerland.
|Schweizerischer Nationalfonds SCOPES|
Prof. F.-K. Thielemann's group
Theoretical Nuclear Astrophysics activities range from nuclear physics issues (e.g. cross section predictions for strong and weak interaction processes and properties of nuclei far from stability) to numerical simulations of explosive astrophysical events (e.g. supernovae , X-ray bursts, and binary neutron star mergers). A major focus exists on nucleosynthesis contributions of these objects to galactic evolution.
- Astronomische Gesellschaft 2012
- EU FP7 Infrastructure Joint Research Program ENSAR
- Lise Meitner Prize 2012 - Awarded to Prof. F.-K. Thielemann and Prof. K. Langanke.
- NIC-IX Satellite Workshop (2006)
Prof. D. Trautmann's group
The main activity of our group are theoretical calculations of electromagnetic interactions, mostly in collisions of atoms and ions. At low energies we study excitation or ionization of common and exotic atoms, with focus also on the semi-classical regime and transition to chaos. At higher energies we study Coulomb excitation of so-called halo nuclei, multiple pair and antihydrogen production, and the use of relativistic heavy ion collisions for photon-photon or photon-hadron interactions.
Prof. B. Binggeli's group
Our group is representing traditional observational astronomy. Topics of interest range from wide binary star statistics in our Galaxy, the structure and distribution of dwarf galaxies, the morphology of galaxies in general, and near-field cosmology. Most of our recent work is based on the Sloan Digital Sky Survey database. For more information see the group's homepage.
Prof. (SNF) M. Liebendörfer's group
Macroscopic phenomena in nature - in astrophysics and on Earth - often originate from the interaction of tightly coupled microscopic processes with different characteristic length and time scales. We develop efficient transport/hydrodynamics algorithms in the context of gravitational collapse and supernova explosions. A reliable numerical link between the input physics and the observables in distant astrophysical objects provides new information about matter under otherwise inaccessible conditions, or vice versa, allows the prediction of a large-scale evolution based on well-known input physics. For more information see the group's homepage.
Dr. I. Cherchneff's group
Our group interest is the understanding and the modelling of the synthesis of molecules and dust in our local and far universe from a theoretical point of view. We focus on the major dust providers in galaxies, i.e., stars in their late stages of evolution and develop chemical/physical models describing the formation of molecules and dust in evolved stellar environments. The resulting theoretical predictions are further tested by observations in the optical, infrared, submillimetre and millimetre ranges using telescope facilities worldwide. For more information see the group's homepage.