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Quantum statistics |
| Particle statistics |
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| Maxwell-Boltzmann statistics |
| Bose-Einstein statistics |
| Fermi-Dirac statistics |
| Parastatistics |
| Anyonic statistics |
| Braid statistics |
Particle statistics refers to the particular description of particles in statistical mechanics.
Contents |
In classical mechanics all the particles (fundamental and composites particles, atoms, molecules, electrons, etc.) in the system are considered distinguishable. This means that one can label and track each individual particle in a system. As a consequence changing the position of any two particles in the system leads to a completely different configuration of the entire system. Furthermore there is no restriction on placing more than one particle in any given state accessible to the system. Classical statistics is called Maxwell-Boltzmann Statistics (or M-B Statistics).
The fundamental feature of quantum mechanics that distinguishes it from classical mechanics is that particles of a particular type are indistinguishable from one another. This means that in an assemble consisting of similar particles, interchanging any two particles does not lead to a new configuration of the system (in the language of quantum mechanics: the wavefunction of the system is invariant with respect to the interchange of the constituent particles). In case of a system consisting of particles belonging to different nature (for example electrons and protons), the wavefunction of the system is invariant separately for the assembly of the two particles.
While this difference between classical and quantum description of systems is fundamental to all of quantum statistics, it is further divided into the following two classes on the basis of symmetry of the system.
In Bose-Einstein statistics (B-E Statistics) interchanging any two particles of the system leaves the resultant system in a symmetric state. That is, the wavefunction of the system before interchanging equals the wavefunction of the system after interchanging.
It is important to emphasize that the wavefunction of the system has not changed itself. This has very important consequences on the state of the system: There is no restriction to the number of particles that can be placed in a single state (accessible to the system). It is found that the particles that obey Bose-Einstein statistics are the ones which have integral spins. Examples of such particles include photons and helium-4 atoms. Such system is called the Bose-Einstein condensate where all particles of the assembly exist in the same state.
In Fermi-Dirac statistics (F-D statistics) interchanging any two particles of the system leaves the resultant system in a antisymmetric state. That is, the wavefunction of the system before interchanging is the wavefunction of the system after interchanging, with an overall minus sign.
Again it should be noted that the wavefunction of the system itself does not change. The consequence of the negative sign on the Fermi-Dirac statistics can be understood in the following way:
Suppose that the particles that are interchanged belong to the same state. Since the particles are considered indistinguishable from one another then changing the coordinates of the particles should not have any change on the system's wavefunction (because by our assumptions the particles are in the same state). Therefore, the wavefunction before interchanging similar states equals the wavefunction before interchanging similar states.
Combining (or adding, literally speaking) the above statement with the fundamental asymmetry of the Fermi-Dirac system leads us to conclude that the wavefunction of the system before interchanging equals zero.
This shows that in Fermi-Dirac statistics, more than one particle cannot occupy a single state accessible to the system. This is called Pauli's exclusion principle.
It is found that only half integral particles obey the Fermi-Dirac statistics. This includes, electrons, protons, Helium-3 etc.
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