This note explains the following topics: Elementary particles, Order of
Magnitude Calculations, Reaction rates and Cross Section, The Electromagnetic
Interaction, The Weak Interaction, STRANGENESS, Quark Mixing, Spontaneous
Symmetry Breaking, the Higgs Scalar, Neutrino Oscillation, Neutrino Experiments
and The Muon Anomaly.
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 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 book includes theoretical
aspects, with chapters outlining the generation model and a charged Higgs boson
model as alternative scenarios to the Standard Model. An introduction is
provided to postulated axion photon interactions and associated photon
dispersion in magnetized media. The book concludes with a chapter tackling
potential radiation hazards associated with extremely weakly interacting
neutrinos if produced in copious amounts with future high-energy muon-collider
facilities.
This note explains the following
topics: Particles and Forces, Wave Equations and Anti Particles, The
Electromagnetic Field, Perturbation Theory and Fermi’s Golden Rule,
Electromagnetic Scattering of Spinless Particles, The Dirac Equation, Solutions
of the Dirac Equation, The Weak Interaction, Local Gauge Invariance, Electroweak
Theory.
This note explains the following topics: Elementary particles, Order of
Magnitude Calculations, Reaction rates and Cross Section, The Electromagnetic
Interaction, The Weak Interaction, STRANGENESS, Quark Mixing, Spontaneous
Symmetry Breaking, the Higgs Scalar, Neutrino Oscillation, Neutrino Experiments
and The Muon Anomaly.