In theoretical condensed matter physics and quantum field theory, bosonization is a mathematical procedure by which a system of interacting fermions in (1+1) dimensions can be transformed to a system of massless, non-interacting bosons. [1] The method of bosonization was conceived independently by particle physicists Sidney Coleman and Stanley Mandelstam; and condensed matter physicists Daniel C. Mattis and Alan Luther in 1975.[1]
In particle physics, however, the boson is interacting, cf, the Sine-Gordon model, and notably through topological interactions,[2] cf. Wess–Zumino–Witten model.
The basic physical idea behind bosonization is that particle-hole excitations are bosonic in character. However, it was shown by Tomonaga in 1950 that this principle is only valid in one-dimensional systems.[3] Bosonization is an effective field theory that focuses on low-energy excitations.[4]
Mathematical descriptions
editThis section may be confusing or unclear to readers. (August 2020) |
A pair of chiral fermions , one being the conjugate variable of the other, can be described in terms of a chiral boson where the currents of these two models are related by where composite operators must be defined by a regularization and a subsequent renormalization.
Examples
editIn particle physics
editThe standard example in particle physics, for a Dirac field in (1+1) dimensions, is the equivalence between the massive Thirring model (MTM) and the quantum Sine-Gordon model. Sidney Coleman showed the Thirring model is S-dual to the sine-Gordon model. The fundamental fermions of the Thirring model correspond to the solitons (bosons) of the sine-Gordon model.[5]
In condensed matter
editThe Luttinger liquid model, proposed by Tomonaga and reformulated by J.M. Luttinger, describes electrons in one-dimensional electrical conductors under second-order interactions. Daniel C. Mattis and Elliot H. Lieb proved in 1965[6] that electrons could be modeled as bosonic interactions. The response of the electron density to an external perturbation can be treated as plasmonic waves. This model predicts the emergence of spin–charge separation.
See also
editReferences
edit- ^ a b Gogolin, Alexander O. (2004). Bosonization and Strongly Correlated Systems. Cambridge University Press. ISBN 978-0-521-61719-2.
- ^ Coleman, S. (1975). "Quantum sine-Gordon equation as the massive Thirring model" Physical Review D11 2088; Witten, E. (1984). "Non-abelian bosonization in two dimensions", Communications in Mathematical Physics 92 455-472. online
- ^ Sénéchal, David (1999). "An introduction to bosonization". CRM Series in Mathematical Physics. Springer. pp. 139–186. arXiv:cond-mat/9908262. Bibcode:2004tmsc.book..139S. doi:10.1007/0-387-21717-7_4. ISBN 978-0-387-00895-0. S2CID 15395499.
{{cite book}}
:|journal=
ignored (help); Missing or empty|title=
(help) - ^ Fisher, Matthew P. A.; Glazman, Leonid I. (1997). Sohn, Lydia (ed.). Mesoscopic electron transport. Springer. pp. cond–mat/9610037. arXiv:cond-mat/9610037. Bibcode:1996cond.mat.10037F. ISBN 978-0-7923-4737-8.
- ^ Coleman, S. (1975). "Quantum sine-Gordon equation as the massive Thirring model". Physical Review D. 11 (8): 2088–2097. Bibcode:1975PhRvD..11.2088C. doi:10.1103/PhysRevD.11.2088.
- ^ Mattis, Daniel C.; Lieb, Elliot H. (February 1965). Exact solution of a many-fermion system and its associated boson field. Vol. 6. pp. 98–106. Bibcode:1994boso.book...98M. doi:10.1142/9789812812650_0008. ISBN 978-981-02-1847-8.
{{cite book}}
:|journal=
ignored (help)