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MX3010: STOCHASTIC PROCESSES (2014-2015)

Last modified: 28 Jun 2018 10:27


Course Overview

Statistical physics derives the phenomenological laws of thermodynamics from the probabilistic treatment of the underlying microscopic system.  Statistical physics, together with quantum mechanics and the theory of relativity, is a cornerstone in our modern understanding of the physical world. 

Through this course, you will gain a better understanding of fundamental physical concepts such as entropy and thermodynamic irreversibility, and you will learn how derive some simple thermodynamic properties of gases and solids.

The final part of the course is devoted to an introduction to stochastic systems, which are widely used in many different fields such as physics, biology and economics.



Course Details

Study Type Undergraduate Level 3
Term First Term Credit Points 15 credits (7.5 ECTS credits)
Campus None. Sustained Study No
Co-ordinators
  • Dr Francesco Ginelli

What courses & programmes must have been taken before this course?

None.

What other courses must be taken with this course?

None.

What courses cannot be taken with this course?

None.

Are there a limited number of places available?

No

Course Description

This course provides an introduction to statistical physics and simple stochastic processes. A brief review of thermodynamics is offered in the first lectures to set up the background needed to understand the foundations of statistical mechanics. The microcanonical and canonical ensembles are discussed in details and it is shown as thermodynamical irreversibility emerges statistically from reversible microscopic dynamics. Quantum statistics are also discussed. Applications are limited to non-interacting systems and include computing the specific heats of solids and of monoatomic and simple diatomic gases, blackbody radiation, Fermi gases and ferromagnetism. Ising magnetism is briefly discussed in mean field approximation.

In addition, the course gives an introduction to stochastic processes. We shall first discuss Brownian motion and random walks, introducing the concepts of Master and Fokker-Planck equations for one-dimensional random walks. This offers a simple context in which the central limit theorem can be introduced. Finally, we will discuss the principle of detailed balance as a necessary and sufficient condition for a system to be in thermodynamic equilibrium.






Contact Teaching Time

Information on contact teaching time is available from the course guide.

Teaching Breakdown

More Information about Week Numbers


Details, including assessments, may be subject to change until 30 August 2024 for 1st term courses and 20 December 2024 for 2nd term courses.

Summative Assessments

1st Attempt:70 % final examination and 30% continuous assessment exercises. Resit: 100% Examination Only the mark obtained at first attempt can count towards Honours classification

Formative Assessment

By means of class tutorials and dialogue with the lecturer.

Feedback

Feedback on assessments will be given within two weeks of receipt and immediately during classroom exercises.

Course Learning Outcomes

None.

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