30558 - STATISTICAL AND QUANTUM PHYSICS
Course offered to incoming exchange students
Department of Computing Sciences
MARC JEAN MEZARD
Suggested background knowledge
Mission & Content Summary
MISSION
CONTENT SUMMARY
Part A: Quantum Physics
1- Why quantum mechanics? Introduction to quantum phenomena
2- Schrödinger equation
3- Quantum measurements
4- Energy quantization
5- Principle of quantum mechanics
6- Two state systems
7- Approximation methods
8- Angular momentum
9- Quantum description of atoms
10- Entanglement, Einstein-Podolsky-Rosen paradox, Bell’s inequalities
11- Introduction to quantum computing
Part B: Statistical Physics
1- Why statistical physics? From microscopics to macroscopics
2- Statistical descriptions
3- Thermodynamics seen from the statistical physics viewpoint
4- Ideal gas
5- Interacting systems, phase transitions, ferromagnetism
6- Dynamics and equilibrium
7- Statistical physics and Data Dcience
8- Statistical physics and Machine Learning
Intended Learning Outcomes (ILO)
KNOWLEDGE AND UNDERSTANDING
- understand the description of quantum systems
- understand quantum spins
- understand the quantum theory of atomic structure
- understand the concepts of entanglement and quantum measurement
- understand the principles of statistical physics and their relations to thermodynamics
- understand the theory of ideal gases
- understand the notion of phase transition
- undestand the dynamics of statistical physics systems and the approach to equilibrium
- understand the principles of application of statistical physics in data science and machine learning
APPLYING KNOWLEDGE AND UNDERSTANDING
- Study quantum properties of particles in external potentials
- Use perturbative methods
- Study quantum properties of spin 1/2 particles
- Study properties of ideal gases, classical, fermions and bosons
- Study phase transitions using mean-field theory
- Understand the dynamical properties of simple many-body systems
- Use the simplest mean-field methods in data analysis and inverse problems
Teaching methods
- Face-to-face lectures
- Exercises (exercises, database, software etc.)
DETAILS
Exercises are an important part of the course. Regularly, a part of the lectures time will be dedicated to exercises in the class, illustrating and complementing the lectures.
Assessment methods
Continuous assessment | Partial exams | General exam | |
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x | x |
ATTENDING AND NOT ATTENDING STUDENTS
The total grade has a maximum of 32 points.
The grade of 30 cum laude corresponds to 31 or 32 points
In order to pass the exam, the students must obtain a grade of 18 points at least.
The exam is not open-book. Any material apart from the one provided by the instructors is forbidden. A sheet contianing basic formulas and fundamental constants will be provided.
Teaching materials
ATTENDING AND NOT ATTENDING STUDENTS
- Quantum mechanics, J-L Basdevant and J. Dalibard, Springer
- Fundamentals of Statistical and Thermal Physics, Frederick Reif, Mac Graw Hill (optional)
- “From statistical physics to data-driven modelling”, Simona Cocco, Rémi Monasson and Francesco Zamponi, Oxford University Press 2023
Exercises will be provided, as well as additional teaching material when needed