Dec 17, 2019; Colloquium
Physikalisches Kolloquium: Energy extraction from accreting black holes
Lehrstuhl für Astronomie und Astrophysik
Fakultät für Physik und Astronomie
Julius-Maximilians-Universität Würzburg
01062 Dresden
Veranstaltungseinladung als pdf-Download.
Kurzfassung: Interstellar space is crowded with black holes, objects so compact that not even light can escape from them. Recent detections of gravitational waves from mergers of black holes or the picture of a shadow imprinted by the supermassive black hole in the giant elliptical galaxy Messier 87 onto the glow of surrounding gas are celebrated as breathtaking confirmations of general relativity. Now, the flickering of gamma rays from remote extragalactic objects adds another window to witness the physical realm of Einstein’s legacy: Lightning flashes at TeV energies lasting only a few minutes driven by particle acceleration close the ergosphere of supermassive black holes confirm energy extraction from the spinning black holes by electrodynamical processes predicted by Penrose (1969) and by Blandford and Znajek (1977). The association of gamma-ray flares with high-energy neutrinos indicates that proton acceleration plays a key role, possibly solving the century-old question about where the highest energy cosmic ray nuclei in nature originate from.
Biographie: 1983-1989: Physics studies in Heidelberg and Bonn (Dipl.-phys.). / 1989-1992:
PhD at MPI für Radioastronomie in Bonn (Dr. rer. nat.), advisor: Peter Biermann / 1992-1993: Postdoc at MPIfR / 1993-1999: Akademischer Rat a.Z., Universitäts-Sternwarte Göttingen / 1995: ITP UC Santa Barbara; Ludwig-Biermann-Award (Astronomische Gesellschaft) / 1997: Habilitation in Physics / 1999-2001: Heisenberg Fellow / since 2001:
Chair of Astronomy and Astrophysics, JMU Würzburg
Key research areas: High-energy radiation processes, extragalactic jets, compact objects, metagalactic background radiation, indirect dark matter detection