ELEMENTI DI ASTRONOMIA GALATTICA E COSMOLOGIAAcademic Year 2019/2020 - 3° Year
Credit Value: 6
Scientific field: FIS/05 - Astronomy and astrophysics
Taught classes: 42 hours
Term / Semester: 2°
The aim of the course is to get the students acquainted with the fundamental concepts in the fields of Galactic Astronomy and theoretical and observational Cosmology, particularly in what concerns their interconnections for the scientific investigation on the formation and evolution of the components and structures of the Universe. Based on these concepts, the relevance of recent achievements in the fields of Stellar Formation, Galactic Archaeology, and Near Field Cosmology is outlined.
Knowledge and understanding
Students will gain discriminating knowledge of the physical processes leading to the formation and evolution of stars, stellar systems, galaxies, and large scale structures of the Universe. This includes understanding the role of gravitation, baryonic and non-baryonic matter, and dark energy in the cosmological models as well as the principles of the deductive method in this research field.
Applying knowledge and understanding
Students will gain the skills needed to apply knowledge to problem solving in the fields of stellar formation, kinematics of stellar systems and the Galaxy, the chemical evolution of the Galaxy, structure and stellar populations of the Galaxy and to the evolution of the major components of the Universe.
Students will gain the skills needed to compare observational data with theoretical models and plan experiments, if only at a conceptual level, aiming at revealing possible deviation from the models’ predictions.
Students will gain confidence in dealing and discussing fundamental concepts in the field of Cosmology and Galactic Astronomy, including those regarding the recent advances in Star Formation, Galactic Archaeology, and Near Field Cosmology, at professional and non-professional level.
Students will get acquainted with introductory literature in the field of Galactic Astronomy and Cosmology and will be able to selectively search the scientific literature for further information regarding specific issues.
The main concepts are taught in front lectures, which include practical examples. Learning effectiveness is monitored through written exercises and intermediate tests.
Detailed Course Content
Astronomical measurements. Properties of stars. Stellar populations. Interstellar medium. Star formation. Stellar clusters.
Morphology of galaxies. Components of the Galaxy. Kinematics of stellar clusters. Kinematics of galaxies. Introduction to the dynamics of stellar clusters. Introduction to the dynamics of the Galaxy
The cosmic distance scale. Hubble law. Cosmic background radiation. Clusters of galaxies and the large scale structure of the Universe.
Introduction to general relativity. The cosmological principle. The Robertson-Walker metric. The Hubble constant. Redshift. Deceleration parameter. Baryonic and non-baryonic matter. The dark energy. The LCDM model. The Friedmann models. Formation of structures in the Universe. Near-field cosmology. The thermal history of the Universe. Inflationary Universe.
 J. Binney, Merrifield M., Galactic Astronomy, Princeton University Press (1998)
 J. Rich, “Fundamentals of Cosmology”, Springer-Verlag, 2001
T. Padmanabhan, “Theoretical Astrophysics”, Cambridge University Press, 2000
P. Coles & F. Lucchin, “Cosmology. The Origin and Evolution of Cosmic Structure”, Wiley & Sons, 1995
S. Bonometto, “Cosmologia & Cosmologie, Zanichelli, 2008
M. S. Longair, “Galaxy Formation”, Springer, 2008