Found 5 relevant results in 1.18s where lecturer="Massimiliano Grazzini"
The course presents the quantum field theory of the strong interaction (quantum chromodynamics, QCD) and discusses its applications to particle physics observables.
This year we celebrate the tenth anniversary of the discovery of the Higgs boson.With this course the students will receive a detailed introduction to the physics of the Higgs boson in the Standard Model. They will acquire the necessary theoretical background and learn about the main experimental methods used to study the physics the Higgs boson.
Many-body quantum physics rests on symmetry considerations that lead to two kinds of particles, fermions and bosons. Formal techniques include Hartree-Fock theory and second-quantization techniques, as well as quantum statistics with ensembles. Few- and many-body systems include atoms, molecules, the Fermi sea, elastic chains, radiation and its interaction with matter, and ideal quantum gases.
Many-body quantum physics rests on symmetry considerations that lead to two kinds of particles, fermions and bosons. Formal techniques include Hartree-Fock theory and second-quantization techniques, as well as quantum statistics with ensembles. Few- and many-body systems include atoms, molecules, the Fermi sea, elastic chains, radiation and its interaction with matter, and ideal quantum gases.
A) Electroweak interactions- From the Fermi theory to the Standard Model (SM)- Spontaneous symmetry breaking and Higgs mechanism- Precision tests of the electroweak theoryB) Flavour Physics- The flavour sector of the SM- Neutral-meson mixing and rare decaysC) The SM as an effective theory- SM limitations and beyond-SM directions- Neutrino masses and neutrino oscillations