ANALYTICAL AND STATISTICAL MECHANICS
cod. 1004552

Academic year 2014/15
2° year of course - First semester
Professor
Raffaella BURIONI
Academic discipline
Fisica teorica, modelli e metodi matematici (FIS/02)
Field
Teorico e dei fondamenti della fisica
Type of training activity
Characterising
78 hours
of face-to-face activities
9 credits
hub: PARMA
course unit
in - - -

Learning objectives

The student will acquire the basic theoretical concepts in Lagrangian and Hamiltonian mechanics. She/he will understand the principles leading to the study of macroscopic systems and the basic concepts in statistical mechanics. The student will be able to apply these methods to calculate the thermodynamical properties of macroscopic systems at equilibrium, starting from the statistical distribution of microscopic variables in phase space, in simple physical systems. She/he will develop learning skills and she/he will be able to identify the relevant points in a physical problem, the validity of relations and their applicability.

Prerequisites

- - -

Course unit content

Introduction to Analytical Mechanics.

Statistical Mechanics of Microcanonical, Canonical and Gran Canonical Ensembles.

Applications of the classical ensembles.

Full programme

- Classical Mechanics in an arbitrary reference frame. Constraints, virtual displacements, generalized lagrangian coordinates. The Lagrangian of a physical systems and the Lagrange equations. Symmetries and conservation laws. Noether's theorem. Small oscillations, normal modes. The Legendre transform and the Hamiltonian. Hamilton's equations. Configuration space and phase space. Poisson brackets.

- Variational principles and Lagrange and Hamilton equations. Elements of calculus of variations. Canonical transformations. Elements of perturbation theory. Examples of relevant Lagrangians and Hamiltonians of physical systems: central forces, changed particles in an electromagnetic field. Infinite degrees of freedom: the vibrating string.

- The statistical description of a macroscopic system. Systems with many degrees of freedom and classical mechanics. Average values without dynamics: statistical ensembles and probability measures. Liouville theorem. The problems of the microscopic approach. Temporal averages and the ergodic hypothesis. Recurrence times and macroscopic variables. How and if equilibrium is reached.
Brief review of thermodynamics: extensive and intensive variables, thermodynamic potentials, Legendre transformations, response functions.

-Microcanonical distribution. Boltzmann entropy and its properties. Additivity. Microcanonical classical ideal gas. Gibbs paradox.

- Canonical distribution. The partition function and the Helmotz free energy. Energy fluctuation in the canonical ensemble. Fluctuation and response. Maxwell distribution. Equipartition. Equivalence between microcanonical e canonical ensembles. Canonical Ideal Gas.

- Gran canonical distribution. Gran canonical partition function and pressure. Chemical potential. Gran canonical Ideal Gas.

- Entropy and information theory: Shannon entropy.

- Dinamics vs Statistical Mechianics in computer simulations: molecular dynamics, Metropolis Monte Carlo. Markov chains and detailed balance.

- Spin models in statistical mechanics.

- Recent interdisciplinary application of statistical mechanics.

Bibliography

H. Goldstein- C. Poole - J. Safko, Classical Mechanics

L.D. Laundau - E.M. Lifsits, Mechanics

L.D. Laundau - E.M. Lifsits, Statistical Physics

Lecture notes.

K. Huang - Statistical Mechanics

Teaching methods

Lectures and exercices

Assessment methods and criteria

Oral and Written examination

Other information

Support activity: tutor activity during the course, material from web sites on advanced subjects

2030 agenda goals for sustainable development

- - -