Course Identification

Title:

Quantum field theory 1

Code:

20241052

Lecturers and Teaching Assistants

Lecturers:

Prof. Kfir Blum

TA's:

Netanel Barel, Noga Bashan, Omri Rosner, Evyatar Tulipman, Luca Teodori

Course Schedule and Location

Year:

2024

Semester:

Second Semester

When / Where:

Monday, 11:15 - 13:00, Weissman, Auditorium
Wednesday, 11:15 - 13:00, Weissman, Auditorium

Tutorials
Monday, 09:15 - 11:00, Weissman, Auditorium

First Lecture:

08/04/2024

End date:

10/07/2024

Field of Study, Course Type and Credit Points

Physical Sciences: Lecture; 5.00 points
Chemical Sciences: Elective; 5.00 points

Comments

On April 8 the course will be held in Zoom.

Prerequisites

QM I, II

Restrictions

Participants:

40

Language of Instruction

English

Attendance and participation

Expected and Recommended

Grade Type

Numerical (out of 100)

Grade Breakdown (in %)

Assignments:

33%

Final:

67%

Evaluation Type

Examination

Scheduled date 1

Date / due date

N/A

Location

N/A

Time

-

Remarks

N/A

Scheduled date 2

Date / due date

N/A

Location

N/A

Time

-

Remarks

N/A

Estimated Weekly Independent Workload (in hours)

6

Syllabus

1) Introduction. Conventions. Perturbation theory and Feynman diagrams from Path Integrals (scalars and fermions). Computation of tree-level diagrams. The S-matrix.

2) Computation of one-loop diagrams, regularization and renormalization (perturbative). Dimensional regularization. Renormalizable field theories. The optical theorem and the LSZ reduction formula.

3) Scale-dependence of coupling constants and beta functions, the renormalization group, the Wilsonian effective action, marginal and relevant operators, fixed points.

4) QED – quantization of gauge fields, gauge fixing and the Faddeev-Popov procedure, Feynman diagrams, Ward identities. Computations at tree-level and at one-loop, renormalization.

5) An introduction to non-Abelian gauge theories. Qualitative discussion of non-perturbative features of QCD.

6) (Time permitting) Symmetries in QFT, Goldstone’s theorem, the Higgs mechanism.

Learning Outcomes

Upon successful completion of this course students should be able to:

Perform perturbative computations, both at tree-level and at higher orders (loops), in any quantum field theory, including scalars, fermions, and gauge fields. This includes regularizing and renormalizing the theory if necessary, and computing the beta functions indicating how coupling constants vary with the scale. Students should be able to perform both computations of correlation functions, and of the S-matrix.
Relate quantitative QFT calculations to high-energy particle physical phenomena, e.g. scattering cross sections or particle decay processes.
Take more advanced courses, including QFT2 and advanced courses like supersymmetry, and other related topics.

Reading List

The main book that will be used in the first part of the course M. Peskin and J. Schroeder, "An introduction to quantum field theory", but there are many other good books on this topic, and it is recommended to look at several different books. A more complete reading list will be given at the beginning of the semester.

Website

N/A