Ball Dependence of thermodynamic potentials of the number of particles in the system. Second law of thermodynamics. Classification of phase transitions. Fundamentals of statistical and thermal physics. Faculty of Electrical Engineering and Computer Science. Teaching methods — Czech English.
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Shaktizshura The partition function, partition sum integral. Law of mass action. The transition to quantum statistics. For the 3rd year of the Kvawnica study. First law of thermodynamics. Reversible and irreversible processes, the criterion of reversibility of the process.
Descriptions of systems of many particles. Time evolution of probability density. Meeting with international participation. Implications of third law of thermodynamics.
First-order phase transitions, phase diagram. Dependence of thermodynamic potentials of the number of particles in the system. Quantisation of velocity and energy, velocity distribution, equation of state, heat capacities cV and cP, isothermal, adiabatic and Joule expansions, real gas. Fluctuation theory, equivalence of statistical ensembles. Identical particles, quantum statistical ensembles, the classical limit. Force, work, and heat. The lecture aims to give an overview on basic concepts, methods and results of classical thermodynamics and statistical physics.
The first law of thermodynamics, heat capacity. Third law of thermodynamics. Statistical calculation of thermodynamic quantities. Fundamentals of statistical mechanics Classical statistical mechanics Macroscopic and microscopic states, ergodic systems and thermodynamic limit. Statistical Mechanics, 2nd edition, J. Annotation — Czech English. Entropy and thermodynamic statiwtick. Classical statistical mechanics Macroscopic and microscopic states, ergodic systems and thermodynamic limit.
Collect the basic principles of thermodynamics and statistical physics Define the physical quantities for describing statistical ensembles with great numer of particles Apply the simple mathematical methods for describing of the thermodynamic phenomene Interpret the knowlidges from the mathematical statistics for solving of statistical physical problems.
Some features may not be available. Correlation functions and response functions, fluctuation-dissipation theorem. Measurement of macroscopic parameters temperature, heat capacity, compressibility and relations between it. Systems with variable contents, Grand canonical Gibbs distribution, chemical potential, grand partition function sumFermi-Dirac distribution, Bose-Einstein distribution, electron gas, Planck distribution, Debye theory of heat capacity.
Asymmetric diatomic gas, vacancies in solid, Gibbs paradox. Related Posts
KVASNICA STATISTICK FYZIKA PDF
Kazigal Thermodynamic properties of photons file. For the 3rd year of the TF study. Dependence of thermodynamic quantities on mass. Deterministic methods — molecular dynamics, stochastic methods — Monte Carlo.
Faculty of Mechanical Engineering. University Study Programmes Reversible and irreversible processes, the criterion sfatistick reversibility of the process. Edited by Ralph Baierlein. Temperature, the meaning of temperature for large systems, thermal equilibrium, Boltzmann distribution, the meaning of temperature for small systems, partition function, negative temperature. The interpretation of basic ideas and laws of thermodynamics is based on its statistical description. The transition to quantum statistics.
Meeting with international participation. Kvasnica, Jozef Boltzmann-Gibbs definition, kanonical distribution, the law of increase of entropy, configurational entropy, the connection between equilibrium entropy and heat, Third law of thermodynamics. Second law kvqsnica thermodynamics. Phase transitions classification, Clausius-Clapeyron equation, Ehrenfest equations, Landau theory of phase transition, the behavior near critical point.