Late stages of stars, supernovae and gamma-ray bursts  

This course addresses the late stages of stellar evolution, with focus on the massive stars which end their lives as supernovae and/or gamma ray bursts. The theory and stages of nuclear burning from helium ignition to the formation of an iron core are laid out, and the origin the elements in the periodic table is discussed. The important role of neutrino cooling for the now more rapid and qualitatively different stellar evolution is emphasized. The connection between stellar properties, such as mass and metallicity, and observational classifications are discussed in the context of the supernova that results. The course further treats the physics of supernova explosions, and how advanced computer simulations have improved our understanding of these. We review the fundamental processes forming the light curve and spectra of the supernova, and diagnostic methods to determine the structure of the ejecta. Results from theory and observations are combined to describe the landscape of successful explosions versus failed ones leading to black hole formation, and associations between different stellar classes and supernova types. Gamma ray bursts are reviewed, and the connection of these to the most massive and rapidly rotating stars in the Universe is discussed. We study also briefly exotic transients such as superluminous supernovae and kilonovae. Learnining outcomes: - describe the star's late evolutionary stages, both on microphysical and macrocopic scales, as well as the connection between stellar properties and observational classes. - use publicly available software to make simulations of a star’s evolution, and analyse how changed assumptions affect the evolution. - account for the different phases in a supernova explosion, observational properties of supernovae, and classifications based on these properties. - deduce and apply analytic formulae to estimate the physical parameters of a supernova from observed light curves and spectra. - describe fundamental phenomenology of gamma-ray bursts, models for their emission processes, and relation to the central engine. - couple together results from observations, simulations, and theory to differentiate between well established and more speculative properties of massive stars, supernovae, and gamma ray bursts. - argue for the origin of each element in the periodic table.
Presential
English
Late stages of stars, supernovae and gamma-ray bursts
English

Funded by the European Union. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or HaDEA. Neither the European Union nor the granting authority can be held responsible for them. The statements made herein do not necessarily have the consent or agreement of the ASTRAIOS Consortium. These represent the opinion and findings of the author(s).