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In mathematics, the '''Springer representations''' are certain representations of the [[Weyl group]] ''W'' associated to [[unipotent|unipotent conjugacy classes]] of a [[Semisimple algebraic group|semisimple]] [[algebraic group]] ''G''. There is another parameter involved, a representation of a certain finite group ''A''(''u'') canonically determined by the unipotent conjugacy class. To each pair (''u'', φ) consisting of a unipotent element ''u'' of ''G'' and an irreducible representation ''φ'' of ''A''(''u''), one can associate either an irreducible representation of the Weyl group, or 0. The association
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: <math> (u,\phi) \mapsto E_{u,\phi} \quad u\in U(G), \phi\in\widehat{A(u)}, E_{u,\phi}\in\widehat{W} </math>
depends only on the conjugacy class of ''u'' and generates a correspondence between the irreducible representations of the Weyl group and the pairs  (''u'', &phi;) modulo conjugation, called the '''Springer correspondence'''. It is known that every irreducible representation of ''W'' occurs exactly once in the correspondence, although &phi; may be a non-trivial representation. The Springer correspondence has been described explicitly in all cases by Lusztig, Spaltenstein and Shoji. The correspondence, along with its generalizations due to Lusztig, plays a key role in [[Lusztig's classification]] of the [[irreducible representation]]s of [[finite groups of Lie type]].
 
== Construction ==
Several approaches to Springer correspondence have been developed. [[T. A. Springer]]'s original construction (1976) proceeded by defining an action of ''W'' on the top-dimensional [[l-adic cohomology]] groups of the [[algebraic variety]] ''B''<sub>''u''</sub> of the [[Borel subgroup]]s of ''G'' containing a given unipotent element ''u'' of a [[semisimple group|semisimple algebraic group]] ''G'' over a finite field. This construction was generalized by Lusztig (1981), who also eliminated some technical assumptions. Springer later gave a different construction (1978), using the ordinary cohomology with rational coefficients and complex algebraic groups.
 
Kazhdan and Lusztig found a topological construction of Springer representations using the [[Steinberg variety]] and, allegedly, discovered [[Kazhdan–Lusztig polynomial]]s in the process. Generalized Springer correspondence has been studied by Lusztig-Spaltenstein (1985) and by Lusztig in his work on [[character sheaves]]. Borho and MacPherson (1983) gave yet another construction of the Springer correspondence.
 
== Example ==
 
For the [[special linear group]] ''SL''<sub>''n''</sub>, the unipotent conjugacy classes are parametrized by [[partition (number theory)|partitions]] of ''n'': if ''u'' is a unipotent element, the corresponding partition is given by the sizes of the [[Jordan block]]s of ''u''. All groups ''A''(''u'') are trivial.
 
The Weyl group ''W'' is the [[symmetric group]] ''S''<sub>''n''</sub> on ''n'' letters. Its irreducible representations over a field of characteristic zero are also parametrized by the partitions of ''n''. 
The Springer correspondence in this case is a bijection, and in the standard parametrizations, it is given by transposition of the partitions  (so that the trivial representation of the Weyl group corresponds to the regular unipotent class, and the [[sign representation]] corresponds to the identity element of ''G'').
 
== Applications ==
 
Springer correspondence turned out to be closely related to the classification of [[primitive ideal]]s in the [[universal enveloping algebra]] of a complex semisimple [[Lie algebra]], both as a general principle and as a technical tool. Many important results are due to [[Anthony Joseph (mathematician)|Anthony Joseph]]. A geometric approach was developed by Borho, [[Jean-Luc Brylinski|Brylinski]] and [[Robert MacPherson (mathematician)|MacPherson]].
 
==References==
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*Walter Borho, Jean-Luc Brylinski and Robert MacPherson ''Springer's Weyl group representations through characteristic classes of cone bundles'' {{DOI|10.1007/BF01458071}} Mathematische Annalen Volume 278, Numbers 1–4 / March, 1987 pages 273–289
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*Walter Borho, Jean-Luc Brylinski and Robert MacPherson. ''Nilpotent orbits, primitive ideals, and characteristic classes''. A geometric perspective in ring theory. Progress in Mathematics, 78. Birkhäuser Boston, Inc., Boston, MA, 1989. ISBN 0-8176-3473-8
*W. Borho and R.MacPherson. ''Partial resolutions of nilpotent varieties''. Analysis and topology on singular spaces, II, III (Luminy, 1981), 23–74, Astérisque, 101-102, Soc. Math. France, Paris, 1983.
*D. Kazhdan and G. Lusztig [http://dx.doi.org/10.1016/0001-8708(80)90005-5 ''A topological approach to Springer's representation''], Adv. Math. 38 (1980) 222–228.
*G. Lusztig. ''Green polynomials and singularities of unipotent classes''. Adv. in Math. 42 (1981), 169–178.
*G. Lusztig and N. Spaltenstein. ''On the generalized Springer correspondence for classical groups''. Advanced Studies in Pure Mathematics, vol. 6 (1985), 289–316.
*N. Spaltenstein. ''On the generalized Springer correspondence for exceptional groups''. Advanced Studies in Pure Mathematics, vol. 6 (1985), 317–338.
*{{citation|last=Springer|first= T. A. |title=Trigonometric sums, Green functions of finite groups and representations of Weyl groups|journal=Invent. Math.|volume= 36 |year=1976|pages=173–207|id={{MathSciNet|id=0442103}} |doi=10.1007/BF01390009}}
*Springer, T. A. ''A construction of representations of Weyl groups. '' Invent. Math.  44  (1978), no. 3, 279–293. {{MathSciNet|id=0491988}} {{DOI|10.1007/BF01403165}}
*Springer, T. A. ''Quelques applications de la cohomologie intersection''. Séminaire Bourbaki, exposé 589, Astérisque 92–93 (1982).
<!--- this may not be the best reference
*Springer, T. A. ''Représentations de groupes de Weyl et éléments nilpotents d'algèbres de Lie.'' Séminaire d'Algèbre Paul Dubreil, 29ème année (Paris, 1975–1976), pp. 86–92. Lecture Notes in Math., 586. Springer, Berlin, 1977. {{MathSciNet|id=0573081}}
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[[Category:Representation theory of groups]]

Latest revision as of 11:34, 25 June 2014

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