Introduction to Particle Physics by Thomas Gajdosik
Introduction to Particle Physics by Thomas Gajdosik
Introduction to Particle Physics by Thomas Gajdosik
This note
explains the following topics: electron, photon, neutron, Strange particles,
particle decays and interactions, The fundamental importance of symmetries,
conservation laws, Particles of the Standard Model, The Higgs Mechanism ,
symmetry breaking.
This note covers the following topics: Elementary Particles, Quark
models, Unitary Symmetries and Application in the Physics of Elementary
Particles,Method of Young Tableaux and its Applications, Nuclear and Particle
Detectors.
The contents of the lecture
notes are: Basics of elementary particle physics, Fundamental
interactions/forces, Conservation laws , Symmetries, Building blocks of matter,
Conclusion with the Fundamental Model of particles.
Author(s): Dr. B. C. Chanyal, Department of Physics, G.
B. Pant University of Agriculture and Technology
Topics covered in this lecture notes are :
Quantum Field Theory, Strong interactions: Quantum Chromodynamics, Electroweak
interactions: The Standard Model of Particle Physics, Beyond the renormalizable
Standard Model, Drawbacks of the Standard Model.
Author(s): Instituto de Física da
Universidade de São Paulo, Brasil
This note
explains the following topics: electron, photon, neutron, Strange particles,
particle decays and interactions, The fundamental importance of symmetries,
conservation laws, Particles of the Standard Model, The Higgs Mechanism ,
symmetry breaking.
This note covers the
following topics: Concepts of Quantum Field Theory and the Standard Model,
Construction Of The Standard Model, One Generation of Leptons and Quarks,
Fermion Masses, Three Generations of Quarks and Lepton, The Structure of the
Strong Interactions, Phenomenology of the Strong Interactions, Topology of Gauge
Fields, The Strong CP-Problem.
This note addresses current research
topics in particle and astroparticle physics, and focuses on aspects of current
and future experiments in the area. It consists of 2 major parts: Current
Front-line Research, and Experiments and Methods, representing 7.5 ECTS credits
together.
This
note covers the following topics: standard model qualitatively, review of QM and
relativity, symmetries, Feynman toy model, quantum electrodynamics, quantum,
electroweak interaction, the standard model, if time selected applications in
new physics.
This note explains the
following topics: Elementary particles, Fermions and bosons, Particles and
anti-particles, Scattering experiments, A role model: Quantum electrodynamics,
Invariances and quantum numbers, Strong interactions, Weak interactions, Beyond
the standard model.