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In mathematics, a Zuckerman functor is used to construct representations of real reductive Lie groups from representations of Levi subgroups. They were introduced by Gregg Zuckerman (1978). The Bernstein functor is closely related.

Notation and terminology

G is a connected reductive real affine algebraic group (for simplicity; the theory works for more general groups), and g is the Lie algebra of G. K is a maximal compact subgroup of G.
L is a Levi subgroup of G, the centralizer of a compact connected abelian subgroup, and *l is the Lie algebra of L.
A representation of K is called K-finite if every vector is contained in a finite dimensional representation of K. Denote by W_K the subspace of K-finite vectors of a representation W of K.
A (g,K)-module is a vector space with compatible actions of g and K, on which the action of K is K-finite.
R(g,K) is the Hecke algebra of G of all distributions on G with support in K that are left and right K finite. This is a ring which does not have an identity but has an approximate identity, and the approximately unital R(g,K)- modules are the same as (g,K) modules.

Definition

The Zuckerman functor Γ is defined by

\Gamma _{g,L\cap K}^{g,K}(W)=\hom _{R(g,L\cap K)}(R(g,K),W)_{K}

and the Bernstein functor Π is defined by

\Pi _{g,L\cap K}^{g,K}(W)=R(g,K)\otimes _{R(g,L\cap K)}W.

Applications

Template:Empty section

References

David A. Vogan, Representations of real reductive Lie groups, ISBN 3-7643-3037-6
A. Knapp, David A. Vogan, Cohomological induction and unitary representations, ISBN 0-691-03756-6 preface review by D. Barbasch Template:MathSciNet
David A. Vogan Unitary Representations of Reductive Lie Groups. (AM-118) (Annals of Mathematics Studies) ISBN 0-691-08482-3
G. J. Zuckerman, Construction of representations via derived functors, unpublished lecture series at the I. A. S., 1978.

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+{{dablink|This article is about the Zuckerman induction functor, which is not the same as the (Zuckerman) [[translation functor]].}}
+In [[mathematics]], a '''Zuckerman functor''' is used to construct representations of real [[Reductive group|reductive]] [[Lie group]]s from representations of [[Levi subgroup]]s. They were introduced by [[Gregg Zuckerman]] (1978). The '''Bernstein functor''' is closely related.
+==Notation and terminology==
+*''G'' is a connected reductive real affine [[algebraic group]] (for simplicity; the theory works for more general groups), and ''g'' is the [[Lie algebra]] of ''G''. ''K'' is a [[maximal compact subgroup]] of ''G''.
+*''L'' is a [[Levi subgroup]] of ''G'', the centralizer of a compact connected abelian subgroup, and *''l'' is the Lie algebra of ''L''.
+*A representation of ''K'' is called '''[[K-finite]]''' if every vector is contained in a finite dimensional representation of ''K''. Denote by ''W''<sub>''K''</sub> the subspace of ''K''-finite vectors of a representation ''W''  of ''K''.
+*A '''(g,K)-module''' is a vector space with compatible actions of ''g'' and ''K'', on which the action of ''K'' is ''K''-finite.
+*R(''g'',''K'') is the [[Hecke algebra]] of ''G'' of all distributions on ''G'' with support in ''K'' that are left and right ''K'' finite. This is a ring which does not have an identity but has an [[approximate identity]], and the approximately unital R(''g'',''K'')- modules are the same as (''g'',''K'') modules.
+==Definition==
+The Zuckerman functor Γ is defined by
+:<math>\Gamma^{g,K}_{g,L\cap K}(W) = \hom_{R(g,L\cap K)}(R(g,K),W)_K</math>
+and the Bernstein functor Π is defined by
+:<math>\Pi^{g,K}_{g,L\cap K}(W) = R(g,K)\otimes_{R(g,L\cap K)}W.</math>
+==Applications==
+{{Empty section|date=July 2010}}
+==References==
+*[[David A. Vogan]], ''Representations of real reductive Lie groups'', ISBN 3-7643-3037-6
+*[[A. Knapp]], David A. Vogan, ''Cohomological induction and unitary representations'', ISBN 0-691-03756-6 [http://www.math.sunysb.edu/~aknapp/books/brown/kv-preface.pdf preface][http://www.ams.org/bull/1999-36-03/S0273-0979-99-00782-X/S0273-0979-99-00782-X.pdf review by D. Barbasch]{{MathSciNet|id=1330919}}
+*David A. Vogan ''Unitary Representations of Reductive Lie Groups.'' (AM-118) (Annals of Mathematics Studies) ISBN 0-691-08482-3
+*G. J. Zuckerman, ''Construction of representations via derived functors'', unpublished lecture series at the I. A. S., 1978.
+[[Category:Representation theory]]
+[[Category:Functors]]

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Notation and terminology

Definition

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Notation and terminology

Definition

Applications

References

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