Boson

For other meanings, see Boson (disambiguation).
The Standard Model of elementary particles, with the gauge bosons in the last column

In particle physics, bosons are subatomic particles that obey Bose–Einstein statistics. Several bosons can occupy the same quantum state. The word boson derives from the name of Satyendra Nath Bose.[1]

Bosons contrast with fermions, which obey Fermi–Dirac statistics. Two or more fermions cannot occupy the same quantum state.

Since bosons with the same energy can occupy the same place in space, bosons are often force carrier particles. In contrast, fermions are usually associated with matter (although in quantum physics the distinction between the two concepts is not clear cut).

Bosons may be either elementary, like photons, or composite, like mesons. Some composite bosons do not satisfy the criteria for Bose-Einstein statistics and are not truly bosons (e.g. helium-4 atoms); a more accurate term for such composite particles would be "bosonic-composites".

All observed bosons have integer spin, as opposed to fermions, which have half-integer spin. This is in accordance with the spin-statistics theorem which states that in any reasonable relativistic quantum field theory, particles with integer spin are bosons, while particles with half-integer spin are fermions.

While most bosons are composite particles, in the Standard Model, there are five bosons which are elementary:

Unlike the gauge bosons, the Higgs boson has not yet been observed experimentally.[2]

Composite bosons are important in superfluidity and other applications of Bose–Einstein condensates.

Contents

Definition and basic properties

By definition, bosons are particles which obey Bose–Einstein statistics: when one swaps two bosons, the wavefunction of the system is unchanged.[3] Fermions, on the other hand, obey Fermi–Dirac statistics and the Pauli exclusion principle: two fermions cannot occupy the same quantum state as each other, resulting in a "rigidity" or "stiffness" of matter which includes fermions. Thus fermions are sometimes said to be the constituents of matter, while bosons are said to be the particles that transmit interactions (force carriers), or the constituents of radiation. The quantum fields of bosons are bosonic fields, obeying canonical commutation relations.

The properties of lasers and masers, superfluid helium-4 and Bose–Einstein condensates are all consequences of statistics of bosons. Another result is that the spectrum of a photon gas in thermal equilibrium is a Planck spectrum, one example of which is black-body radiation; another is the thermal radiation of the opaque early Universe seen today as microwave background radiation. Interaction of virtual bosons with real fermions are called fundamental interactions, and these result in all forces we know. The bosons involved in these interactions are called gauge bosons.

All known elementary and composite particles are bosons or fermions, depending on their spin: particles with half-integer spin are fermions; particles with integer spin are bosons. In the framework of nonrelativistic quantum mechanics, this is a purely empirical observation. However, in relativistic quantum field theory, the spin-statistics theorem shows that half-integer spin particles cannot be bosons and integer spin particles cannot be fermions.[4]

In large systems, the difference between bosonic and fermionic statistics is only apparent at large densities—when their wave functions overlap. At low densities, both types of statistics are well approximated by Maxwell-Boltzmann statistics, which is described by classical mechanics.

Elementary bosons

See also: List of particles#Bosons

All observed elementary particles are either fermions or bosons. The observed elementary bosons are all gauge bosons: photons, W and Z bosons and gluons.

In addition, the standard model postulates the existence of Higgs bosons, which give other particles their mass via the Higgs mechanism.

Finally, many approaches to quantum gravity postulate a force carrier for gravity, the graviton, which is a boson of spin 2.

Composite bosons

See also: List of particles#Composite particles

Composite particles (such as hadrons, nuclei, and atoms) can be bosons or fermions depending on their constituents. More precisely, because of the relation between spin and statistics, a particle containing an even number of fermions is a boson, since it has integer spin.

Examples include the following:

The number of bosons within a composite particle made up of simple particles bound with a potential has no effect on whether it is a boson or a fermion.

Fermionic or bosonic behavior of a composite particle (or system) is only seen at large (compared to size of the system) distance. At proximity, where spatial structure begins to be important, a composite particle (or system) behaves according to its constituent makeup. For example, two atoms of helium-4 cannot share the same space if it is comparable by size to the size of the inner structure of the helium atom itself (~10−10 m)—despite bosonic properties of the helium-4 atoms. Thus, liquid helium has finite density comparable to the density of ordinary liquid matter.

Other Bosons

The Graviton is a theoretical Gauge Boson which, while not a member of the Standard Model, is perfectly plausable. However, due to the nature of the Graviton it is never likely to be discovered, as it is impossible to do so with any physically reasonable detector.[5]

See also

Notes

  1. "boson (dictionary entry)". Merriam-Webster's Online Dictionary. http://www.merriam-webster.com/dictionary/boson. Retrieved 2010-03-21. 
  2. Standard Model of Particle Physics, SLAC Large Detector (SLD) group, Stanford Linear Accelerator Center.
  3. Srednicki (2007), pages 28-29
  4. Sakurai (1994), page 362
  5. Rothman, Tony; and Stephen Boughn (November 2006). "Can Gravitons be Detected?". Foundations of Physics 36 (12): 1801–1825. doi:10.1007/s10701-006-9081-9. http://arxiv.org/abs/gr-qc/0601043. Retrieved 2007-07-02. 

References

Particles in physics
Elementary
u · d · c · s · t · b
e · e+ · μ · μ+ · τ · τ+ · νe · νe · νμ · νμ · ντ · ντ
Bosons
γ · g · W± · Z
Others
Ghosts
Superpartners
Gauginos
Gluino · Gravitino
Others
Axino · Chargino · Higgsino · Neutralino  · Sfermion
Others
A0 · Dilaton · G · H0 · J · Tachyon · X · Y · W' · Z' · Sterile neutrino
Composite
Baryons / Hyperons
N (p · n) · Δ · Λ · Σ · Ξ · Ω
Mesons / Quarkonia
π · ρ · η · η′ · φ · ω · J/ψ · ϒ · θ · K · B · D · T
Others
Atomic nuclei · Atoms · Diquarks · Exotic atoms (Positronium · Muonium · Onia) · Superatoms · Molecules
Hypothetical
Exotic hadrons
Exotic baryons
Dibaryon · Pentaquark
Exotic mesons
Glueball · Tetraquark
Others
Mesonic molecule · Pomeron
Quasiparticles
Davydov soliton · Exciton · Magnon · Phonon · Plasmaron · Plasmon · Polariton · Polaron · Roton
Lists
List of particles · List of quasiparticles · List of baryons · List of mesons · Timeline of particle discoveries
Wikipedia books
Book:Hadronic Matter · Book:Particles of the Standard Model · Book:Leptons · Book:Quarks