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| 0321-4215 | Field Theory 2 | ||||||||||||||||||||||||||||||||||
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| FACULTY OF EXACT SCIENCES | |||||||||||||||||||||||||||||||||||
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Quantum Field theory 2- Syllabus
Instructor
Jacob Sonnenschein
Email :cobi@post.tau.ac.il
Academic Year, Semesters
[Msc first year one semester]
Number of Hours/ Credits
[4 weekly hours]
Mandatory/Elective
[mandatory for all elementary particle physics theory]
Prerequisites
[Quantum Field theory 1
Year in program & how often given, if relevant
Given every year
Course overview – short abstract
Yhe topics of the course are1: Feynman rules for \phi^4 theory and QED
2 Elementary processes in QED in the tree level
3 Loop divergences: vertex function Feynman variables
4: Pauli Villars and dimensional regularization. Vacuum polarization and electron self energy
5. Renormalization perturbation theory
6 Renormalization group equation Wilson approach Callan Symanzic equation beta and gamma functions
7 : Spontaneous symmetry breaking . Effective action
8. Aspects of group theory. Non abelian gauge theories
9: Non abelian gauge theories BRST quantization
10-13 QCD. Elementary process. Loop divergences. Beta function from Calan Symanzic and from background field effective action
[Author Name]
Learning outcomes – short description (if you don’t have LOs, then don’t write anything in this part)
You might love the look of the classic, professional font in this syllabus as much as we do. But it’s also easy to get exactly the look you want. On the Design tab of the ribbon, check out the Fonts gallery to preview options right in your document and then click to apply one you like.
Assessment: coursework and grade structure
(for example)
Assignments – 50%
Mid exam
Final exams – 80%
Week-by-week content, assignments and reading
(for example)
Week 1: Feynman rules for \phi^4 theory and QED Exercise I
Week 2 Elementary processes in QED in the tree level Exercise 2
Week 3 Loop divergences: vertex function Feynman variables Exercise 3
Week 4: Pauli Villars and dimensional regularization. Vacuum polarization and electron self energy Exercise 4
Week 5. Renormalization perturbation theory Exercise 5
Week 6 Renormalization group equation Wilson approach Callan Symanzic equation beta and gamma functions Exercise 6
Week 7 : Spontaneous symmetry breaking . Effective action Exercise 7
Week 8 Aspects of group theory. Non abelian gauge theories Exercise 8
Week 9: Non abelian gauge theories BRST quantization Exercise 9
Week 10-13 QCD. Elementary process. Loop divergences. Beta function from Calan Symanzic and from background field effective action Exercise I0
…Required text – in language of origin (if Hebrew or Arabic, no need to translate it)
Peskin Schroder ``An Introduction to Quantum Field Theory"
Bjorken Drell QFT
Itzykson and Zuber ``Quantum Field Theory"
D. Gross ``Lectures on QFT
Y. Frishman J. Sonnenschein ``Non Perturbative QFT"
[Publication Name]