When a physical system involves many coupled degrees of freedom it is usually impossible

to solve exactly the equations of motion describing the microscopic time evolution of the system

(e.g. Newton's equations for more than two interacting particles). This is the notorious 'many-body

problem' which occupies the time of a multitude of physicists worldwide.

Fortunately, many quantities of interest do not require detailed knowledge of individual particle

motion, but are average quantities (e.g. the pressure of a gas at a boundary arises from many

collisions with the gas molecules): A statistical description becomes appropriate - the 'statistical

mechanics' of Boltzmann and Gibbs.

In this colloquium I will discuss the statistical mechanics of liquids and how this can be cast in the

form of a variational theory - the density functional theory (for which Walter Kohn received the 1998

Nobel prize in chemistry). All quantities of interest can be calculated by minimizing a certain functional

with respect to the particle density distribution. Particular attention will be given to the very simple

model system of hard spheres for which geometrical arguments can be employed to construct

accurate approximate functionals.

When? | 14.05.2019 17:15 - 18:15 |
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Where? | PER 08 2.52 Chemin du Musée 3 1700 Fribourg |

speaker | Brader Joseph
Université de Fribourg, Département de Physics |

Contact | Département de Mathématiques Brader Joseph joseph.brader@unifr.ch Chemin du Musée 3 1700 Fribourg 026 300 89 14 |