FYSS4515 Applied Quantum Field Theory (11 cr)
Description
Review of functional methods
Systematics of renormalization, BPHZ-method
Renormalization of QED and Ward identities, explicit 1-loop renormalization
Infrared divergences and soft brehmsstrahlung
Renormalization group: Wilsonian flow, Callan-Symantzik equation
Beta functions and anomalous dimensions, one-loop running of couplings
Renormalization of Yang-Mills theory, asymptotic freedom
Parton model and quark model for QCD
Critical phenomena and epsilon-expansion, critical exponents
Effective action and renormalization-group-improved effective potential
Renormalization of spontaneously broken theories
Standard model of electroweak interactions
Precision electroweak observables
Quantum anomalies: chiral and conformal anomalies and ABJ-anomalies
Learning outcomes
After this course, the student will
understand fully the content of the renormalization program
be able to apply renormalization methods to compute higher order corrections to scattering processes and to study the scale dependence of couplings
be able to understand the particular features of renormalization of Yang-Mills gauge theories and be able to compute critical exponents using field theory methods
will understand the meaning of the effective action and effective potential and knows how to compute quantum corrections to them
will be able to fully understand the structure and quantization of the standard model of electroweak interactions and know how to compute precision electroweak observables
will understand how chiral and ABJ anomalies arise and what they mean for renormalizability
Description of prerequisites
Study materials
Literature
- Peskin & Schroder, An introduction to Quantum Field theory, Westview Press, ISBN 0-201-50397-2
- Srednicki, Quantum field theory, Cambridge, ISBN 987-0-521-86449-7
Completion methods
Method 1
Method 2
Teaching (11 cr)
Interactive lectures and assignments + traditional examination or home examination.
Independent study (11 cr)
Self-study, exercises and exam.