Course details
Semester
- Autumn 2023
- Monday, October 2nd to Friday, December 8th
Hours
- Live lecture hours
- 10
- Recorded lecture hours
- 0
- Total advised study hours
- 40
Timetable
- Thursdays
- 13:05 - 13:55 (UK)
Description
After motivating the relation between strings and conformal field theories using the Polyakov action, we develop the basic elements of two-dimensional conformal field theories, and illustrate them using the special case of the theory of free bosons.
We use this example to explain the quantisation of strings in the conformal gauge and provide the space-time interpretation of the physical string states.
Time permitting we will discuss the dimensional reduction of strings, T-duality, the relation between non-abelian gauge symmetries and Kac-Moody algebras, and orbifolds.
Prerequisites
Basic knowledge in quantum field theory, general relativity, group theory and differential geometry is helpful.
Syllabus
- Action principles for relativistic particles.
- Action principles for relativistic strings. Nambu-Goto and Polyakov action. Conformal gauge and conformal invariance.
- Conformal invariance in two dimensions. Witt and Virasoro algebra. Two-dimensional conformal field theories.
- Conformal field theory of free bosons and its relation to strings.
- Quantisation of strings using conformal field theory of free bosons. Space-time interpretation of states. Momentum and angular momentum. Null states and gauge symmetries.
- Analysis of physical states. Examples of physical states: Tachyon, photon, antisymmetric tensor, graviton, dilaton. Elements of the representation theory of the Poincare group.
- Conformal field theories with extended symmetries, Kac-Moody algebras. Example: Conformal field theory of compact bosons.
- Compactification of strings on a circle. Spectrum, symmetry enhancement. T-duality.
- Orbifolds.
- Outlook
Lecturer
-
Dr Thomas Mohaupt
- University
- University of Liverpool
Bibliography
Follow the link for a book to take you to the relevant Google Book Search page
You may be able to preview the book there and see links to places where you can buy the book. There is also link marked 'Find this book in a library' - this sometimes works well, but not always - you will need to enter your location, but it will be saved after you do that for the first time.
- A First Course in String Theory (Barton Zwiebach, book)
- A Primer on String Theory (Volker Schomerus, book)
- A Short Introduction to String Theory (Thomas Mohaupt, book)
- Basic Concepts of String Theory (Ralph Blumenhagen, Dieter Lüst and Stefan Theisen, book)
- String Theory and M-Theory (Katrin Becker, Melanie Becker and John H. Schwarz, book)
- String Theory: Volume 1, An Introduction to the Bosonic String (Joseph Polchinski, book)
- Superstring Theory (Michael B. Green, John H. Schwarz and Edward Witten, book)
Assessment
The assessment for this course will be released on Monday 8th January 2024 at 00:00 and is due in before Friday 19th January 2024 at 11:00.
Assessment for all MAGIC courses is via take-home exam which will be made available at the release date (the start of the exam period).
You will need to upload a PDF file with your own attempted solutions by the due date (the end of the exam period).
If you have kept up-to-date with the course, the expectation is it should take at most 3 hours’ work to attain the pass mark, which is 50%.
Please note that you are not registered for assessment on this course.
Files
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Lectures
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