You are here: Home > Study > Course units, transferable skills, MOOCs > Course unit catalogue > 2016/2017 Models And Numerical Methods For Physics s

67135 - Models And Numerical Methods For Physics s

Academic Year 2016/2017

  • Moduli: Armando Bazzani (Modulo 1) Giorgio Turchetti (Modulo 2)
  • Teaching Mode: Traditional lectures (Modulo 1) Traditional lectures (Modulo 2)
  • Campus: Bologna
  • Corso: Second cycle degree programme (LM) in Physics (cod. 8025)

    Also valid for Second cycle degree programme (LM) in Physics of the Earth System (cod. 8626)

Learning outcomes

The aim of the course is to provide the tools to build up dynamical models for the evolution of the classical physical systems formed by interacting particles, under the influence of external fields. There will be developed numerical techniques for the solution of the corresponding differential equation  even in the case of fluctuating fields.  In the limit of a large number of particles there will be developed the kinetic and the fluid approximations. In the case of long range interactions the average field equations will be considered, together with self-consistent solutions and the collision models based on stochastic processes.

Course contents

Basic numerical methods: recurrences techniques and their convergence, Newton and bisection methods.  Interpolation and numerical derivation and integration. Solution for linear equations. Functions approximation. Finite difference methods for parabolic and wave equations.

Hamiltonian systems: Canonical transformations. Liouville equations. Perturbation theory and adiabatic limit. Symplectic maps and symplectic integrators. Physical models: time dependent pendulum, three bodies problem, electromagnetic lens.

Stochastic systems: particle dynamics in a fluctuating field. Wiener noise and Langevin equation. Fokker-Planckequation. Master equation and thermodynamics formalism. Models: stochastic oscillator, bistable systems, Markov models.

Extensive systems : kinetic equation for hard spheres. Vlasov equation for long range interactions. Collisions, stochastic diffusion processes and Boltzmann equilibrium. Distribution moments and fluid description. Models: elastic rope, Burger viscous fluid, plasma waves.

 

 

Readings/Bibliography

G. Turchetti  Appunti per Metodi e Modelli Numerici e  libro   Dinamica Classica http://www.physycom.unibo.it/corsi.php.

W. H. Press et al  Numerical recipes  per parte 1  V.I.Arnold Meccanica Classica Editori Riuniti per parte 2. 

Gardiner Handbook of Stochastic Methods  Springer per parte 3. 

R. Balescu Equilibrium and Non-equilibrium Statistical Mechanics Wiley Interscience publication 1975.

A.Vulpiani  Caos and coarse graining in statistical mechanics  per parte 4.  

Teaching methods

ex cathedra lessons

Assessment methods

oral exam and exercises using computer

Office hours

See the website of Armando Bazzani

See the website of Giorgio Turchetti