Quantum Field Theory 1

Course content

This course is an introduction to Quantum Field Theory. Emphasis is on the part of quantum field theory which is not just relativitic quantum mechanics.

The path integral formulation of quantum mechanics is introduced and generalized to field theory. Perturbation theory of quantum field theory is developed, including the notation of Feynman rules and Feynman diagrams. The renormalization group is introduced. Quantum electro-dynamics (QED), the theory of electrons and photons, and quantum chromo-dynamics, the theory of quarks and gluons, are studied as examples of quantum gauge theories.

Education

MSc Programme in Physics

Learning outcome

Knowledge

The goal of the course is to introduce you to quantum field theory, such that you are able to explain in a clear and transparent way the foundations of quantum field theory as well as how to use the theory to perform calculations.

 

Skills

At the end of the course, you are expected to be able to:

  • Derive Feynman rules for specific theories from a Lagrangian via the path integral formalism
  • Draw and evaluate Feynman diagrams for specific theories
  • Apply the framework of regularization and renormalization to specific examples
  • Evaluate simple Feynman integrals
  • Apply symmetry considerations within the context of quantum field theory
  • Use the above to calculate simple observables beyond the leading order of perturbation theory

     

Competences

At the end of the course, you are expected to be able to – within the context of Quantum Field Theory – provide and use meaningful feedback, discuss central theories and concepts with peers, and perform mathematically correct calculations. You should be able to do this alone and with others, using your own curiosity, knowledge, skills and strategies; e.g. in an M.Sc. project.

Lectures and exercise classes

To be announced on Absalon

Knowledge of the Dirac equation and its solutions is an advantage.
Basic knowledge of group theory and previous knowledge of particle physics is beneficial.
Academic qualifications equivalent to a BSc degree is recommended.

Written
Oral
Peer feedback (Students give each other feedback)
ECTS
7,5 ECTS
Type of assessment
Oral examination, 25 min
Type of assessment details
Without preparation time
Aid
Without aids
Marking scale
7-point grading scale
Censorship form
No external censorship
More internal examiners
Criteria for exam assessment

See learning outcome.

Single subject courses (day)

  • Category
  • Hours
  • Lectures
  • 35
  • Preparation
  • 142,5
  • Theory exercises
  • 28
  • Exam
  • 0,5
  • English
  • 206,0

Kursusinformation

Language
English
Course number
NFYK13004U
ECTS
7,5 ECTS
Programme level
Full Degree Master
Duration

1 block

Placement
Block 3
Schedulegroup
A
Capacity
No restriction
The number of seats may be reduced in the late registration period
Studyboard
Study Board of Physics, Chemistry and Nanoscience
Contracting department
  • The Niels Bohr Institute
Contracting faculty
  • Faculty of Science
Course Coordinator
  • Matthias Wilhelm   (16-716578786c6d6577327b6d706c6970714472666d326f7932686f)
Saved on the 28-02-2022

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