ELEMENTI DI FISICA STATISTICA E TEORIA DELL'INFORMAZIONE

Academic Year 2020/2021 - 3° Year
Teaching Staff: Giuseppe FALCI
Credit Value: 6
Scientific field: FIS/02 - Theoretical physics, mathematical models and methods
Taught classes: 42 hours
Term / Semester:

Learning Objectives

The course introduces concepts of statistical mechanics and the necessary theoretical background. We adopt the Information Theoretical approach with a unified treatment of classical and quantum statistics. The course also provides the basis for the understanding of concepts in quantum information and quantum thermodynamics. Both are timely topic from the fundamental point of view and for applications, which students will encounter in their subsequent studies.

  • Knowledge and understanding – Knowledge of the main ideas and theoretical techniques in statistical mechanics for the representation of complex quantum system and the study of their dynamics. Knowledge of some numerical techniques with the software Wolfram-Mathematica.
  • Applying knowledge and understanding – Ability in the application of basic theoretical techniques and approximate schemes for the analysis and the simulation of systems of interest for statistical mechanics.
  • Communication skills – Ability in communication in the field of Statistical Mechanics and Information Theory.
  • Learning skills – Acquiring skills allowing the continuous upgrade of the knowledge in the field, by accessing a research environment and specialized literature.

Course Structure

  • The course is structured in four main parts: (1) Foundational ideas in Statistical Mechanics and Information Theory; (2) Equilibrium classical statistical mechanics; [3] Equilibrium quantum statistical mechanics; The end of the course will be devoted to seminars on selected topics.
  • Introductory material can be found on the web page of the theory group on Condensed Matter & Quantum Technologies (www.dfa.unict.it/it/cmqt e www.dfa.unict.it/en/cmqt).
  • Should the circumstances require online or blended teaching, appropriate modifications to what is hereby stated may be introduced, in order to achieve the main objectives of the course.
  • Learning assessment may also be carried out online, should the conditions require it.

Detailed Course Content

  1. Preliminary concepts Goal of statistical mechanics. Handling incomplete information. Elements of kinetic theory and classical transport. Informazione: definition, information associated with a probability (discrete and continuous). Thermodynamics: from principles to thermodynamic potentials.
  2. Classical Statistical mechanics: equilibrium Canonical formalism. Past, future and irreversibility. Conserved quantities and thermal equilibrium. Principle of maximal (missing) information. Existence and unicity of the solution. Relation with thermodynamics: temperature, adiabatic theorem, work and heat, ideal thermal machines. Equipartition theorem in linear systems. Gibbs paradox. Paramagnets. Gran-canonical ensemble.
  3. Quantum Statistical mechanics: equilibrium Density Matrix. Principle of maximal information. Distinguishable particles: spin systems and quantum computers. Identical particles, ideal quantum gas in second quantization (grand canonical). Fermi gas and metals. Bosons: phonons and specific heat, photons and Bose-Einstein condensation.
  4. Selected topic (only one!) -- Physical basis of the postulates: statistical ensembles, decoherence. Small deviations from equilibrium: Onsager relations, Einstein relation, fluctuation-dissipation theorem. Nonequilibrium: Boltzmann equations and H theorem. Jarzynski relation and Crooks fluctuation theorem.

Textbook Information

[1] Amnon Katz, Principles of Statistical, Mechanics. The Information Theory Approach, Freeman, San Francisco, 1967
[2] Carlo Di Castro e Roberto Raimondi, Statistical Mechanics and Applications in Condensed Matter, Cambridge University Press, 2015.
[3] G. Falci, Lecture notes on Statistical Physics and Information Theory, 2020.
[4] D. Arovas, Lecture Notes on Thermodynamics and Statistical Mechanics (A Work in Progress), available on line, 2019.
[5] K. Huang, Introduction to Statistical Physics, Chapman & Hall, 2010.
[6] Stephen Wolfram, An Elementary Introduction to the Wolfram Language, Cambridge University Press, 2015.
[7] G. Baumann, Mathematica for Theoretical Physics, Springer, 2005.