. "Other Physics Kas"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "Advanced statistical physics"@en . . "6" . "Statistical physics of interacting gases (Gibbs' formulation of equilibrium state\nthermodynamics of interacting gases. Partition function. Mayer’s cluster expansion. Virial\nexpansion. Beth-Uhlenbeck approach to quantum gases. Equation of state of multicomponent\nplasma with applications to stars. Chemical equilibrium and Saha equation. Gravitational\nequilibrium of stars for different equations of state.) Statistical physics of quantized fields.\n(The method of quantized fields. Low-temperature behavior of Bose gas, Bose-Einstein\ncondensation. Low-lying excitations in Fermi systems. Fermi-liquid theory. Equation of state\nof degenerate matter, white dwarfs, and neutron stars. Weak equilibrium and change\nneutrality conditions. Gravitational equilibrium of white dwarfs and neutron stars.) Phase\ntransitions (Phase transitions in Van-der-Waals gas. Lattice models. Spontaneous\nmagnetization of a ferromagnet. Lattice gas and binary alloys. Ising model in the Bethe\napproximation. Critical exponents. Thermodynamic inequalities. Landau’s theory of second-\norder phase transitions. Crystallization of white dwarf matter. Phase transitions from hadronic\nto quark matter in neutron stars.) Renormalization group approach (Basic scalings. Simple\nexamples of renormalization. General formation of renormalization group equations.\nFluctuation-dissipation theorem. Linear response theory. Photon and neutrino interactions in\nthe stellar matter within the linear response theory.) Fluctuations (Thermodynamic\nfluctuations. Spatial correlations. Fluctuation analysis on the example of Brownian motion.\nStatistical physics of nuclear reaction in stars, pycnonuclear reactions in neutron stars.)" . . "Presential"@en . "FALSE" . . "Master in Astrophysics"@en . . "https://international.uni.wroc.pl/en/admission-full-degree-studies/programmes-english/astrophysics" . "no data" . "Presential"@en . "The program comprises only a few mandatory courses that acquaint you with general foundations of astrophysics, necessary computer simulation tools and data analysis methods, as well as selected observational techniques. This is supplemented by a wide range of elective courses enabling you to deepen your knowledge and skills according to your scientific interest. You can follow astronomy- or physics-oriented study track that will prepare you for the Master project held in the Astronomical Institute or the Institute of Theoretical Physics, respectively.\nIn the course of becoming an educated astrophysicist, you will gain expertize in mathematical modeling, computer simulations and advanced data analysis. You will also develop universal research competencies, including analytical and critical thinking, rigorous evidence-based reasoning, creativity and complex problem solving, active learning, as well as communication and teamwork skills."@en . . . . "2"@en . "TRUE" . . "Master"@en . "no data" . "1000.00" . "Euro"@en . "2150" . "no data" . "The modern job market awaits people with your competencies! Upon graduation, you will be capable of working in academy, R&D institutes and centers of education, as well as in various knowledge-based economy branches, including ICT, high-tech industry or financial institutions. However, you will be particularly well-prepared to undertake PhD studies and continue scientific career."@en . "no data" . "TRUE" . "Upstream"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .