PH5004
Quantum Field Theory
2019-2020
15
7
SCQF level 11
1
Academic year(s): 2019-2020
SCOTCAT credits : 15
ECTS credits : 7
Level : SCQF level 11
Semester: 1
Availability restrictions: Normally only taken in the final year of an MPhys or MSci programme involving the School
Planned timetable:
This module presents an introductory account of the ideas of quantum field theory and of simple applications thereof, including quantization of classical field theories, second quantization of bosons and fermions, solving simple models using second quantization, path integral approach to quantum mechanics and its relation to classical action principles, field integrals for bosons and fermions, the relationship between path integral methods and second quantization, solving many-body quantum problems with mean-field theory, and applications of field theoretic methods to models of magnetism.
Pre-requisite(s): Before taking this module you must pass PH3012 and pass PH3061 and pass PH3062 and pass 1 module from {PH4038, MT4507} and pass 1 module from {PH4028, MT3503}
Weekly contact: 3 lectures or tutorials.
Scheduled learning hours: 32
Guided independent study hours: 118
As used by St Andrews: 2-hour Written Examination = 85%, Coursework = 15%
As defined by QAA
Written examinations : 85%
Practical examinations : 0%
Coursework: 15%
Re-assessment: Oral Re-assessment, capped at grade 7
Module coordinator: Professor J M J Keeling
Module teaching staff: Dr J Keeling
Module coordinator email jmjk@st-andrews.ac.uk
To present an introductory account of the ideas of quantum field theory and of simple applications thereof, including:
Learning Outcomes
By the end of the module, students will have a comprehensive knowledge of the topics covered in the lectures and of their application in solving simple problems. They will be able to:
Synopsis
Coupled quantum harmonic oscillators, canonical quantization of classical field theory, bosonic quantum field theory. Second quantization for bosons.
The path integral treatment of quantum mechanics. Relation to classical principle of least action. Relationship to statistical mechanics.
Second quantization and many body problems. Diagonalizing simple quantum field theories by unitary rotations, Bogoliubov transformation and Fourier transformations. Identifying normal modes. Examples: tight binding problems, Bose condensation of weakly interacting bosons, BCS theory of superconductivity.
Bosonic coherent states and bosonic field integrals. Grassman variables, fermionic coherent states and fermionic field integrals. Matsubara frequencies, Matsubara summation and solving simple problems using functional integration. Application to the same examples as for second quantization.
Models of interacting spins. The Heisenberg model. Representing spins in terms of Holstein-Primakov bosons. Spin wave theory for ferromagnets and antiferromagnets.
Additional information on continuous assessment etc.
Please note that the definitive comments on continuous assessment will be communicated within the module. This section is intended to give an indication of the likely breakdown and timing of the continuous assessment.
As with many other modules, it is working with the ideas covered in lectures that brings a major part of the learning gains. Four assessed problem sets are provided during the semester, and some of the questions are expected to require substantial synthesis of ideas from different parts of this module and prior work. These assessed problem sets will contribute to the 15% of the module grade that comes from this work. In addition, each problem set contains further non-assessed problems for practice in problem solving during revision.
The anticipated schedule is as follows:
Week 0: Revision of quantum mechanics.
Week 1: Ladder operators for harmonic oscillator, chain of oscillators, and continuum limit.
Week 2: Introduction to coordinate path integrals.
Week 3: Using path integrals. Introduction to quantum many-body problems. Unitary and Bogoliubov transforms. Problem set A (Bosonic field theory) due.
Week 4: Tight binding problems. Introduction to mean field theory.
Week 5: Applications of quantum many-body methods: Theories of BEC and superconductivity. Problem set B (Coordinate path integral) due.
Week 7: Introduction to coherent state path integral. Problem set C (Quantum many body problems) due.
Week 8: Evaluating coherent state path integrals.
Week 9: Introduction to quantum magnetism.
Week 10: Quantum magnetism. Problem set D (Coherent state path integral) due
Week 11: Revision, and discussion of final unassessed problem set (Magnetism)
Recommended Books
Please view University online record: http://resourcelists.st-andrews.ac.uk/modules/ph5004.html
General Information
Please also read the general information in the School's honours handbook that is available via st-andrews.ac.uk/physics/staff_students/timetables.php