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PARTITION FUNCTION

PARTITION FUNCTION. Defintion. The partition function Z is an important quantity that encodes the statistical properties of a system in thermodynamic equilibrium. It is a function of temperature and other parameters, such as the volume enclosing a gas. 1. Canonical partition function.

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PARTITION FUNCTION

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  1. PARTITION FUNCTION

  2. Defintion The partition function Z is an important quantity that encodes the statistical properties of a system in thermodynamic equilibrium. It is a function of temperature and other parameters, such as the volume enclosing a gas.

  3. 1. Canonical partition function • 1.1 Definition • 1.2 Meaning and significance • 1.3 Relation to thermodynamic variables

  4. Definition Suppose we have a thermodynamically large system that is in constant thermal contact with the environment, which has temperature T, with both the volume of the system and the number of constituent particles fixed. This kind of system is called a canonical ensemble.

  5. The canonical partition function is where the "inverse temperature" β is conventionally defined as with kB denoting Boltzmann's constant .

  6. In classical statistical mechanics : where h is some infinitesimal quantity with units of action (usually taken to be Planck's constant H is the classical Hamiltonian In quantum mechanics, the partition function is where H is the quantum Hamiltonian operator

  7. Meaning and significance The partition function can be related to thermodynamic properties because it has a very important statistical meaning. The probability Pj that the system occupies microstate j is This is the well-known Boltzmann factor .) The partition function thus plays the role of a normalizing constant (note that it does not depend on j),

  8. Relation to thermodynamic variables The relationships between the partition function and the various thermodynamic parameters of the system. These results can be derived using the method of the previous section and the various thermodynamic relations. the thermodynamic energy is

  9. The variance in the energy (or "energy fluctuation") is The heat capacity is The entropy is

  10. Where F is the Helmholtz free energy defined as F = E - TS, where E is the total energy and S is the entropy, so that

  11. 2 Grand canonical partition function • 2.1 Definition • 2.2 Relation to thermoynamic variables • 2.3 Discussion

  12. Definition can define a grand canonical partition function for a grand canonical ensemble, a system that can exchange both heat and particles with the environment, which has a constant temperature T, volume V, and chemical potential μ.

  13. The grand canonical partition function for an ideal quantum gas is written:

  14. Relation to thermodynamic variables the canonical partition function, the grand canonical partition function can be used to calculate thermodynamic and statistical variables of the system. Defining α=-βμ, the most probable occupation numbers are:

  15. Total number of particles • Variance in total number of particles Internal energy

  16. Variance in internal energy • Pressure Mechanical equation of state

  17. Discussion Before specific results can be obtained from the grand canonical partition function, the energy levels of the system under consideration need to be specified. For example, the particle in a box model or particle in a harmonic oscillator well provide a particular set of energy levels and are a convenient way to discuss the properties of a quantum fluid. (See the gas in a box and gas in a harmonic trap articles for a description of quantum fluids.) These results may be used to construct the grand partition function to describe an ideal Bose gas or Fermi gas, and can be used as well to describe a classical ideal gas.

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