Course manual 2021/2022

Course content

Starting from basic notions of statistical mechanics and quantum theory, students will be progressively introduced to the formalisms and models of modern condensed matter theory. The basic physical principles underlying emergent phenomena will be discussed in reference to (among others) interacting bosonic, fermionic, and spin systems; broken symmetry and magnetism; and electronic structure. The universal applicability of the methods used in these discussions, like Ginzburg-Landau theory, second quantisation, and the construction of effective theories, will be emphasized.

Study materials

Other

Lecture Notes

Objectives

Students will be able to discuss classic results of modern statistical and condensed matter physics.
Students will learn to apply methods of condensed matter physics.
Students will learn to recognise concepts of condensed matter physics, and place them in context.

Teaching methods

Lecture
Self-study
Presentation/symposium
Supervision/feedback meeting

Learning activities

Activity	Hours
Hoorcollege	22
Tentamen	3
Vragenuur	6
Werkcollege	14
Self study	39
Total	84	(3 EC x 28 uur)

Attendance

Requirements concerning attendance (OER-B).

In addition to, or instead of, classes in the form of lectures, the elements of the master’s examination programme often include a practical component as defined in article A-1.2 of part A. The course catalogue contains information on the types of classes in each part of the programme. Attendance during practical components is mandatory.

Additional requirements for this course:

Attendance at lectures and tutorials is mandatory

Assessment

Item and weight	Details
Final grade
0.5 (50%) Final Exam	NAP if missing
0.2 (20%) Mini-exams
0.2 (20%) Presentation	Best of
0.1 (10%) Perusall

Detailed information is available on the Canvas pages for this course.

Inspection of assessed work

All communication will be through Canvas.

Assignments

During the course, students will be asked to:

actively participate in lectures and tutorials,
actively discuss the lecture notes with peers through Perusall,
give a presentation,
do three mini-exams during tutorials,
and make the final exam.

Details on all of these assignments can be found in the Canvas pages for this course.

Fraud and plagiarism

The 'Regulations governing fraud and plagiarism for UvA students' applies to this course. This will be monitored carefully. Upon suspicion of fraud or plagiarism the Examinations Board of the programme will be informed. For the 'Regulations governing fraud and plagiarism for UvA students' see: www.student.uva.nl

Course structure

Weeknummer	Onderwerpen	Studiestof
1	Order and phase transitions	Lecture Notes chapter 1 & 2
2	Order and phase transitions	Lecture Notes chapter 3 Lecture Notes exercise set 1
3	Non-interacting electrons	Lecture Notes chapter 4 & 5
4	Non-interacting electrons	Lecture Notes chapter 6 Lecture Notes exercise set 2
5	Magnetism	Lecture Notes chapter 7 & 8
6	Magnetism	Lecture Notes chapter 9 Lecture Notes exercise set 3
7	Advanced topics	Handouts
8	Exam	Complete Lecture Notes

Timetable

The schedule for this course is published on DataNose.

Additional information

See Canvas for detailed information about this course.

Contact information

Coordinator

dr. J. van Wezel

Owner	Master Physics and Astronomy (joint degree)
Coordinator	dr. J. van Wezel
Part of	Master Mathematics, Master Physics and Astronomy, track Advanced Matter and Energy Physics, Master Physics and Astronomy, track Theoretical Physics, Master Mathematics, specialization Algebra and Geometry, year 1 Master Mathematics, specialization Analysis and Dynamical Systems, year 1 Master Mathematics, specialization Mathematical Physics, year 1 Master Physics and Astronomy (joint degree), track General Physics and Astronomy, Master Mathematics, specialisation Discrete Mathematics and Quantum Information, year 1 Double master Mathematics and Physics,

Condensed Matter Theory 1