NFYK14014U Introduction to String Theory
MSc Programme in Physics
This course gives a basic introduction to string theory. It begins with an introduction to classical string theory and the covariant quantization of the closed string. Then it proceeds to strings in background fields, branes as higher-dimensional objects, quantization of the open string and D-branes, and superstring theory.
Knowledge
The course will begin with an introduction to the action
description of classical relativistic strings, including discussion
of symmetries, constraints and action principle. The course then
turns to quantization of closed bosonic string theory using
covariant quantization, discussing anomalies versus
symmetries in quantized theories and the critical space-time
dimension. Subsequently, the course will cover D-branes, as
extended objects from open strings, and superstring theory.
Finally, it will be reviewed how the AdS/CFT correspondence is a
consequence of superstring theory.
Skills
At the end of the course, the student is expected to:
- Be able to write down and use the Nambu-Goto and Polyakov actions for classical relativistic strings.
- Be able to quantize the open and closed bosonic string and compute the spectrum.
- Be able to explain classical conformal symmetry, its quantum version with Virasoro algebras, and how this is connected to the covariant quantization of the closed string.
- Be able to explain the connection between the critical space-time dimension of string theory and anomalies in the conformal symmetry in two dimensions.
- Be able to understand the main elements of how general relativity arise from string theory.
- Be able to explain how a D-brane is defined from open string theory.
- Be able to explain branes as higher-dimensional objects in higher-dimensional space-times, including branes with charges, and use this for understanding the description of D-branes and the fundamental string.
- Be able to understand the essentials of generalizing the bosonic string to the superstring and to show that the world-sheet action for superstrings is supersymmetric.
- Be able to explain how the AdS/CFT correspondence is a consequence of superstring theory
Competences
This course builds on the of knowledge quantum mechanics, special
and general relativity. The course will provide the students with a
competent background for further studies within this research
field, i.e. a M.Sc. project in theoretical high energy physics. It
will also provide those that plan to continue into experimental
high energy physics or cosmology the necessary background to
understand the physics of string theory.
This course will provide
the students with mathematical tools that have application in a
range of fields within and beyond physics.
Lecture notes by Troels Harmark
Academic qualifications equivalent to a BSc degree is recommended.
- Category
- Hours
- Lectures
- 35
- Preparation
- 149,5
- Exercises
- 21
- Exam
- 0,5
- Total
- 206,0
- Credit
- 7,5 ECTS
- Type of assessment
- Oral examination, 30 minutes (no preparation)
- Aid
- Without aids
- Marking scale
- 7-point grading scale
- Censorship form
- No external censorship
- Exam period
Several internal examiners
- Re-exam
Same as ordinary exam
Criteria for exam assesment
See Learning outcome
Course information
- Language
- English
- Course code
- NFYK14014U
- Credit
- 7,5 ECTS
- Level
- Full Degree Master
- Duration
- 1 block
- Placement
- Block 4
- Schedule
- B
- Course capacity
- No limitation – unless you register in the late-registration period (BSc and MSc) or as a credit or single subject student.
Study board
- Study Board of Physics, Chemistry and Nanoscience
Contracting department
- The Niels Bohr Institute
Contracting faculty
- Faculty of Science
Course Coordinators
- Troels Harmark (7-726b7c776b7c754a786c7338757f386e75)
- Niels Anne Jacob Obers (5-776a6d7a7b48766a7136737d366c73)