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Anyon

 
Sci-Tech Dictionary: anyon
 
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(′an·ē′än)

(quantum mechanics) A particle obeying an unconventional form of quantum statistics, which is characterized by a parameter that can take on any of a continuum of values, just two of which represent Bose-Einstein and Fermi-Dirac statistics.

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Sci-Tech Encyclopedia: Anyons
 
Home > Library > Science > Sci-Tech Encyclopedia

Particles obeying unconventional forms of quantum statistics. For many years it was believed that only two possible forms of quantum statistics, Bose-Einstein and Fermi-Dirac statistics, were possible, but in fact a continuum of possibilities exists. Elementary excitations (quasiparticles) in the fractional quantum Hall effect are anyons.

In quantum mechanics, in the behavior of identical particles there are important dynamical effects that have no classical analog. Thus, in the case of two indistinguishable particles A and B, the amplitude for the process that leads to A arriving at point x while B arrives at point y must be added to the amplitude for the process that leads to A arriving at y while B arrives at x—the so-called exchange process—because the final states cannot be distinguished. Actually the recipe of adding the amplitude for the exchange process is appropriate only for particles obeying Bose-Einstein statistics (bosons); for particles obeying Fermi-Dirac statistics (fermions), this amplitude must be subtracted. See also Fermi-Dirac statistics.

The definition of anyons posits other possible recipes for adding exchange processes, refining the analysis of exchange to take account of the direction in which the exchange takes place. These more general possibilities can be defined only for particles whose motion is restricted to two space dimensions. However, many important materials are effectively two-dimensional, including microelectronic circuitry and the copper oxide layers of high-temperature superconductors. The quantum statistics of the quasiparticles in these systems is under investigation, but the fractional quantized Hall states are known to be anyons. See also Hall effect; Quantum statistics; Superconductivity.

 
Wikipedia: Anyon
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Particle statistics
Maxwell-Boltzmann statistics
Bose–Einstein statistics
Fermi-Dirac statistics
Parastatistics
Anyonic statistics
Braid statistics
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In mathematics and physics, an anyon is a type of particle that occurs only in two-dimensional systems. It is a generalization of the fermion and boson concept.

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In physics

This mathematical concept becomes useful in the physics of two-dimensional systems such as sheets of graphene or the quantum Hall effect.

In space of three or more dimensions, particles are restricted to being fermions or bosons, according to their statistical behaviour. Fermions respect the so-called Fermi-Dirac statistics while bosons respect the Bose-Einstein statistics. In the language of quantum physics this is formulated as the behavior of multiparticle states under the exchange of particles. This is in particular for a two-particle state (in Dirac notation):

\left|\psi_1\psi_2\right\rangle = \pm\left|\psi_2\psi_1\right\rangle

(where the first entry in \left|\dots\right\rangle is the state of particle 1 and the second entry is the state of particle 2. So for example the left hand side is read as "Particle 1 is in state ψ1 and particle 2 in state ψ2"). Here the "+" corresponds to both particles being bosons and the "−" to both particles being fermions (composite states of fermions and bosons are not possible).

In two-dimensional systems, however, quasiparticles can be observed which obey statistics ranging continuously between Fermi-Dirac and Bose-Einstein statistics, as was first shown by Jon Magne Leinaas and Jan Myrheim of the University of Oslo in 1977[1]. In our above example of two particles this looks as follows:

\left|\psi_1\psi_2\right\rangle = e^{i\,\theta}\left|\psi_2\psi_1\right\rangle

With "i" being the imaginary unit from the calculus of complex numbers and θ a real number. Recall that | eiθ | = 1 and e2iπ = 1 as well as eiπ = − 1. So in the case θ = π we recover the Fermi-Dirac statistics (minus sign) and in the case θ = 2π the Bose-Einstein statistics (plus sign). In between we have something different. Frank Wilczek coined the term "anyon"[2] to describe such particles, since they can have any phase when particles are interchanged.

We also may use \theta=2 \pi s\; with particele spin quantum numer s - s is integer for bosons, half integer for fermions, so that

e^{i\,\theta} = e^{2\,i \pi s} = (-1)^{2\,s}   or   \left|\psi_1\psi_2\right\rangle = (-1)^{2\,s}\left|\psi_2\psi_1\right\rangle.

Topological basis

In more than two dimensions, the spin-statistics connection states that any multiparticle state has to obey either Bose-Einstein or Fermi-Dirac statistics. This is related to the first homotopy group of SO(n,1) (and also Poincaré(n,1)) with n > 2, which is Z2 (the cyclic group consisting of two elements). Therefore only two possibilities remain. (The details are more involved than that, but this is the crucial point.)

The situation changes in two dimensions. Here the first homotopy group of SO(2,1) (and also Poincaré(2,1)) is Z (infinite cyclic). This means that Spin(2,1) is not the universal cover: it is not simply connected. In detail, there are projective representations of the special orthogonal group SO(2,1) which do not arise from linear representations of SO(2,1), or of its double cover, the spin group Spin(2,1). These representations are called anyons.

This concept also applies to nonrelativistic systems. The relevant part here is that the spatial rotation group is SO(2), which has an infinite first homotopy group.

This fact is also related to the braid groups well known in knot theory. The relation can be understood when one considers the fact that in two dimensions the group of permutations of two particles is no longer the symmetric group S2 (with two elements) but rather the braid group B2 (with an infinite number of elements).

A very different approach to the stability-decoherence problem in quantum computing is to create a topological quantum computer with anyons, quasi-particles used as threads and relying on braid theory to form stable logic gates.[3] [4]

References

  1. ^ Leinaas, J.M.; J. Myrheim (1977-01-11). "On the theory of identical particles". Il Nuovo Cimento B 37 (1): 1-23. doi:10.1007/BF02727953. 
  2. ^ Wilczek, Frank (1982-10-04). "Quantum Mechanics of Fractional-Spin Particles". Physical Review Letters 49 (14): 957-959. doi:10.1103/PhysRevLett.49.957. 
  3. ^ Freedman, Michael; Alexei Kitaev, Michael Larsen, Zhenghan Wang (2002-10-20). "Topological Quantum Computation". Bulletin of the American Mathematical Society 40 (1): 31–38. doi:10.1090/S0273-0979-02-00964-3. 
  4. ^ Monroe, Don, Anyons: The breakthrough quantum computing needs?, New Scientist, 1 October 2008

See also

Further reading

External links


This entry is from Wikipedia, the leading user-contributed encyclopedia. It may not have been reviewed by professional editors (see full disclaimer)

 
 

 

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Sci-Tech Dictionary. McGraw-Hill Dictionary of Scientific and Technical Terms. Copyright © 2003, 1994, 1989, 1984, 1978, 1976, 1974 by McGraw-Hill Companies, Inc. All rights reserved.  Read more
Sci-Tech Encyclopedia. McGraw-Hill Encyclopedia of Science and Technology. Copyright © 2005 by The McGraw-Hill Companies, Inc. All rights reserved.  Read more
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