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# Statistical Physics 2

Vak
2020-2021

Statisitical Physics 1, Quantum Mechanics 2

## Description

The goal of Statistical Physics 2 is to understand the physics behind phase transitions in systems of interacting particles using the statisitical description of ensembles.

The course is structured in five connected themes of increasing complexity that discuss the physics of the different states of matter and the phase transition. Each theme consists of 2 lectures and exercise classes. At least one of the exercise classes will be an open numerical experiment based on python. Themes in Statitical Physics 2:

1. Thermodynamics of Phase Transitions (liquid-gas phase transition, Maxwell construction)
2. Statistical Physics of Interacting Particles (cluster expansion of non-ideal gases)
3. Quantum Statistical Physics (interacting fermions and bosons, Bose-Einstein condensation)
4. Order-disorder Transitions (2D Ising model and mean-field interactions, Landau theory and critical exponennts)
5. Fluctuations (Brownian motion, fluctuation-dissipation, Fokker Planck equation)

The treatment of the topics inside these themes will build on prior knowledge from Statistical Physics 1 and Quantum Mechanics 2 with the goal to describe more realistic systems. This can only be achieved through the use of approximation methods. Throughout the course a strong link is made between theoretical concepts, experimental observation and modern research. Examples will be spread across the various disciplines relevant to the research groups in the institute.

## Course objectives

At the end of the course you will be able to:

• apply the basic concepts of statisitcal physics to simple examples in solid-state physics, biology and finance.

• describe quantum statisitical physics using the quantum canonical ensemble

• explain Bose-Einstein condensation

• use the Metropolis algorithm to compute phase transitions in a two-dimensional Ising model

• construct a mean-field approximation for systems of interacting particles

• explain the use of an order parameter and its role in phase transitions

• analyze interacting systems using Landau theory, critical temperature and critical exponents

• describe systems where fluctuations become important on a macroscopic scale

## Transferable Skills

Listening, problem-solving, team work, communication

## Timetable

Schedule
For detailed information go to Timetable in Brightspace

## Mode of instruction

See Brightspace
Lectures, Exercise Classes and Homework. A solution will be provided to follow these activities online.

## Assessment method

Written exam with homework bonus

## Brightspace

Registration for Brightspace occurs via uSis by registration for a class activity using a class number