Duration
20h Th, 5h Pr
Number of credits
| Master in physics (120 ECTS) | 4 crédits | |||
| Master in space sciences (120 ECTS) | 3 crédits | |||
| Master in physics (60 ECTS) | 4 crédits |
Lecturer
Language(s) of instruction
French language
Organisation and examination
Teaching in the first semester, review in January
Schedule
Units courses prerequisite and corequisite
Prerequisite or corequisite units are presented within each program
Learning unit contents
The aim of this course is to familiarize the student with relativistic quantum mechanics. It essentially covers the relativistic wave equations (Klein-Gordon, Dirac, Maxwell) for spin 0, spin 1/2 or spin 1 particles. It is explained through the formalism of second quantization how such equations imply a bosonic or fermionic character of the associated particles.
Topics of the course in detail:
- special relativity
- Maxwell's equations
- quantization of fields
- Klein-Gordon equation
- Dirac equation
- Pauli equation and its relativistic corrections
Learning outcomes of the learning unit
Principal objectives of this course: - to understand the notion of relativistic covariance and its implications - to get familiarized with the fundamental equations (Maxwell/Klein-Gordon and Dirac) that govern the dynamics of the elementary particles in our universe - to understand the association of the (integer or half-integer) spin with the (bosonic or fermionic) statistics of a particle - to understand how non-relativistic quantum mechanics emerges as limiting case of relativistic quantum mechanics - to prepare for the course "Quantum field theory"
Prerequisite knowledge and skills
Having followed an introductory course on non-relativistic quantum mechanics
Planned learning activities and teaching methods
The course will be given by videoconference. The organisational details will be communicated by email to the students enroled in the course.
Mode of delivery (face to face, distance learning, hybrid learning)
The course will be given "ex cathedra" on the blackboard.
Organisational adjustments related to the current health context
The course will be given by videoconference. The organisational details will be communicated by email to the students enroled in the course.
Recommended or required readings
Recommended literature: - J. Bjorken & S. Drell: "Relativistic Quantum Mechanics" (McGraw-Hill, 1964) - A.S. Davydov: "Quantum Mechanics" (chapter VIII) (Pergamon, 1965) - W. Greiner: "Relativistic Quantum Mechanics: Wave Equations" (Springer 1987) - L.D. Landau & E.M. Lifshits: "Relativistic Quantum Theory" (Pergamon, 1971)
Assessment methods and criteria
Below you will find information on the evaluation methods planned for in-person and remote exams as well as those planned for hybrid sessions. Depending on how the health crisis evolves, the chosen method will be communicated to you no later than one month before the start of the exam session.
The evaluation will be done by an individual oral exam of 30 minutes on the contents of the course.
Work placement(s)
Organizational remarks
Contacts
Peter Schlagheck Département de Physique Université de Liège IPNAS, building B15, office 0/125 Sart Tilman 4000 Liège Phone: 04 366 9043 Email: Peter.Schlagheck@ulg.ac.be http://www.pqs.ulg.ac.be
Items online
lecture notes
lecture notes