Lahun Mathematical Papyri: Difference between revisions
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A | A '''Lie conformal algebra''' is in some sense a generalization of a [[Lie algebra]] in the sense that it too is a "Lie algebra," though a in different pseudo-tensor category. Lie conformal algebras are very closely related to [[vertex algebras]] and have many applications in other areas of algebra and integrable systems. | ||
==Definition and relation to Lie algebras== | |||
A Lie algebra is defined to be a vector space with a skew symmetric bilinear multiplication which satisfies the Jacobi identity. More generally, a Lie algebra is an object, <math>L</math> in the category of vector spaces (read: <math>\mathbb{C}</math>-modules) with a morphism | |||
:<math>[\cdot,\cdot]:L\otimes L\rightarrow L</math> | |||
that is skew-symmetric and satisfies the Jacobi identity. A Lie conformal algebra, then, is an object <math>R</math> in the category of <math>\mathbb{C}[\partial]</math>-modules with morphism | |||
:<math>[\cdot_{\lambda}\cdot]:R\otimes R\rightarrow\mathbb{C}[\lambda]\otimes R</math> | |||
called the lambda bracket, which satisfies modified versions of bilinearity, skew-symmetry and the Jacobi identity: | |||
:<math>[\partial a_\lambda b]=-\lambda[a_\lambda b], [a_\lambda \partial b] = (\lambda + \partial)[a_\lambda b],</math> | |||
:<math>[a_\lambda b]=-[b_{-\lambda-\partial}a], \, </math> | |||
:<math>[a_\lambda [b_\mu c]]-[b_\mu [a_\lambda c]]=[[a_\lambda b]_{\lambda+\mu}c]. \, </math> | |||
One can see that "removing all the lambda's, mu's and partials from the brackets, one simply has the definition of a Lie algebra. | |||
==Examples of Lie conformal algebras== | |||
A simple and very important example of a Lie conformal algebra is the Virasoro conformal algebra. Over <math>\mathbb{C}[\partial]</math> it is generated by a single element <math>L</math> with lambda bracket given by | |||
:<math>[L_ \lambda L] = (2\lambda + \partial)L. \, </math> | |||
In fact, it has been shown by Wakimoto that any Lie conformal algebra with lambda bracket satisfying the Jacobi identity on one generator is actually the Virasoro conformal algebra. | |||
==Classification== | |||
It has been shown that any finitely generated (as a <math>\mathbb{C}[\partial]</math>-module) simple Lie conformal algebra is isomorphic to either the Virasoro conformal algebra, a current conformal algebra or a semi-direct product of the two. | |||
There are also partial classifications of infinite subalgebras of <math>\mathfrak{gc}_n</math> and <math>\mathfrak{cend}_n</math>. | |||
==Generalizations== | |||
{{Empty section|date=January 2011}} | |||
==Use in integrable systems and relation to the calculus of variations== | |||
{{Empty section|date=January 2011}} | |||
==References== | |||
* [[Victor Kac]], "Vertex algebras for beginners". ''University Lecture Series, 10.'' American Mathematical Society, 1998. viii+141 pp. ISBN 0-8218-0634-2 {{Please check ISBN|reason=Check digit (2) does not correspond to calculated figure.}} | |||
{{DEFAULTSORT:Lie Conformal Algebra}} | |||
[[Category:Non-associative algebra]] | |||
[[Category:Lie algebras]] | |||
[[Category:Conformal field theory]] | |||
[[Category:Quantum field theory]] |
Revision as of 21:19, 23 June 2013
A Lie conformal algebra is in some sense a generalization of a Lie algebra in the sense that it too is a "Lie algebra," though a in different pseudo-tensor category. Lie conformal algebras are very closely related to vertex algebras and have many applications in other areas of algebra and integrable systems.
Definition and relation to Lie algebras
A Lie algebra is defined to be a vector space with a skew symmetric bilinear multiplication which satisfies the Jacobi identity. More generally, a Lie algebra is an object, in the category of vector spaces (read: -modules) with a morphism
that is skew-symmetric and satisfies the Jacobi identity. A Lie conformal algebra, then, is an object in the category of -modules with morphism
called the lambda bracket, which satisfies modified versions of bilinearity, skew-symmetry and the Jacobi identity:
One can see that "removing all the lambda's, mu's and partials from the brackets, one simply has the definition of a Lie algebra.
Examples of Lie conformal algebras
A simple and very important example of a Lie conformal algebra is the Virasoro conformal algebra. Over it is generated by a single element with lambda bracket given by
In fact, it has been shown by Wakimoto that any Lie conformal algebra with lambda bracket satisfying the Jacobi identity on one generator is actually the Virasoro conformal algebra.
Classification
It has been shown that any finitely generated (as a -module) simple Lie conformal algebra is isomorphic to either the Virasoro conformal algebra, a current conformal algebra or a semi-direct product of the two.
There are also partial classifications of infinite subalgebras of and .
Generalizations
Use in integrable systems and relation to the calculus of variations
References
- Victor Kac, "Vertex algebras for beginners". University Lecture Series, 10. American Mathematical Society, 1998. viii+141 pp. ISBN 0-8218-0634-2 Template:Please check ISBN