? Credit Points : 10  ? SCQF Level : 11  ? Acronym : PHY-4-VStatPh

This is a course on the statistical physics of interacting particles. We begin by reviewing the fundamental assumptions of equilibrium statistical mechanics focussing on the relation between missing information (or entropy) and probability. We then consider the statistical mechanics of interacting particles and develop important approximation schemes. This leads us to review phase transitions and the unifying phenomenology. We study in detail a simple, microscopic model for phase transitions: the Ising model. We then consider a general theoretical framework known as
Landau Theory. Finally we discuss the issue of dynamics: how does a system approach and explore the state of thermal equilibrium? How does one reconcile microscopic time reversibility with the macroscopic arrow of time?

? This course is not accepting further student enrolments.

? This course is only available to part year visiting students.

? This course is a variant of the following course : U01443

? Pre-requisites : Year 3 Physics.

Home subject area

Undergraduate (School of Physics), (School of Physics, Schedule Q)

? Normal year taken : 4th year

? Delivery Period : Semester 1 (Blocks 1-2)

? Contact Teaching Time : 2 hour(s) per week for 11 weeks

All of the following classes

Type Day Start End Area Lecture Monday 10:00 10:50 KB Lecture Thursday 10:00 10:50 KB

Upon successful completion of this course it is intended that a student will be able to:

1) Define and distinguish between the Boltzmann and Gibbs
entropies

2) Derive the principal ensembles of Statistical Physics
by using the method of Lagrange multipliers to maximise the Gibbs entropy

3) Discuss the many-body problem and be able to formulate and motivate various approximation schemes.

4) Describe the phenomenolgy of phase transitions
in particular Bose-Einstein condensation, liquid-gas transition and ferromagnetic ordering.

5) Formulate the Ising model of phase transitions and be able to motivate and work out various mean-field theories

6) Articulate the paradox of the arrow of time.

7) Formulate mathematical descriptions of dynamics such as Fermi's master equation, Langevin equations and the diffusion equations; solve simple examples of such descriptions such as random walks and Brownian motion

8) Discuss and formulate fluctuation-dissipation relations and linear correlation and response theory

Degree Examination, 100%

The Course Secretary should be the first point of contact for all enquiries.

Course Secretary

Mrs Linda Grieve
Tel : (0131 6)50 5254
Email : linda.grieve@ed.ac.uk

Course Organiser

Dr Martin Evans
Tel : (0131 6)50 5294
Email : M.Evans@ed.ac.uk

School Website : http://www.ph.ed.ac.uk/

College Website : http://www.scieng.ed.ac.uk/