The adjoint representation of a Lie group G is the representation given by the adjoint action of G on the Lie algebra of G (an adjoint action is obtained, roughly, by differentiating a conjugation action.)
admissible
A representation of a real reductive group is called admissible if (1) a maximal compact subgroup K acts as unitary operators and (2) each irreducible representation of K has finite multiplicity.
2.Artin's theorem on induced characters states that a character on a finite group is a rational linear combination of characters induced from cyclic subgroups.
Over an algebraically closed field of characteristic zero, the Borel–Weil–Bott theorem realizes an irreducible representation of a reductive algebraic group as the space of the global sections of a line bundle on a flag variety. (In the positive characteristic case, the construction only produces Weyl modules, which may not be irreducible.)
Brauer's theorem on induced characters states that a character on a finite group is a linear combination with integer coefficients of characters induced from elementary subgroups.
A class functionf on a group G is a function such that ; it is a function on conjugacy classes.
cluster algebra
A cluster algebra is an integral domain with some combinatorial structure on the generators, introduced in an attempt to systematize the notion of a dual canonical basis.
“completely reducible" is another term for "semisimple".
complex
1.A complex representation is a representation of G on a complex vector space. Many authors refer complex representations simply as representations.
2.The complex-conjugate of a complex representation V is the representation with the same underlying additive group V with the linear action of G but with the action of a complex number through complex conjugation.
3.A complex representation is self-conjugate if it is isomorphic to its complex conjugate.
complementary
A complementary representation to a subrepresentation W of a representation V is a representation W' such that V is the direct sum of W and W'.
A cyclic G-module is a G-module generated by a single vector. For example, an irreducible representation is necessarily cyclic.
Dedekind
Dedekind's theorem on linear independence of characters.
defined over
Given a field extension , a representation V of a group G over K is said to be defined over F if for some representation over F such that is induced by ; i.e., . Here, is called an F-form of V (and is not necessarily unique).
The direct sum of representationsV, W is a representation that is the direct sum of the vector spaces together with the linear group action .
discrete
An irreducible representation of a Lie group G is said to be in the discrete series if the matrix coefficients of it are all square integrable. For example, if G is compact, then every irreducible representation of it is in the discrete series.
dominant
The irreducible representations of a simply-connected compact Lie group are indexed by their highest weight. These dominant weights form the lattice points in an orthant in the weight lattice of the Lie group.
dual
1.The dual representation (or the contragredient representation) of a representation V is a representation that is the dual vector space together with the linear group action that preserves the natural pairing
2.A dual canonical basis is a dual of Lusztig's canonical basis.
The Frobenius reciprocity states that for each representation of H and representation of G there is a bijection
that is natural in the sense that is the right adjoint functor to the restriction functor .
fundamental
Fundamental representation: For the irreducible representations of a simply-connected compact Lie group there exists a set of fundamental weights, indexed by the vertices of the Dynkin diagram of G, such that dominant weights are simply non-negative integer linear combinations of the fundamental weights.
The corresponding irreducible representations are the fundamental representations of the Lie group. In particular, from the expansion of a dominant weight in terms of the fundamental weights, one can take a corresponding tensor product of the fundamental representations and extract one copy of the irreducible representation corresponding to that dominant weight.
In the case of the special unitary groupSU(n), the n− 1 fundamental representations are the wedge products
A good filtration of a representation of a reductive groupG is a filtration such that the quotients are isomorphic to where are the line bundles on the flag variety .
Harish-Chandra
1.Harish-Chandra (11 October 1923 – 16 October 1983), an Indian American mathematician.
2.The Harish-Chandra Plancherel theorem.
highest weight
1.Given a complex semisimple Lie algebra , Cartan subalgebra and a choice of a positive Weyl chamber, the highest weight of a representation of is the weight of an -weight vector v such that for every positive root (v is called the highest weight vector).
2.The theorem of the highest weight states (1) two finite-dimensional irreducible representations of are isomorphic if and only if they have the same highest weight and (2) for each dominant integral , there is a finite-dimensional irreducible representation having as its highest weight.
Hom
The Hom representation of representations V, W is a representation with the group action obtained by the vector space identification .
indecomposable
An indecomposable representation is a representation that is not a direct sum of at least two proper subrepresebtations.
is a representation of G that is induced on the H-linear functions ; cf. #Frobenius reciprocity.
2.Depending on applications, it is common to impose further conditions on the functions ; for example, if the functions are required to be compactly supported, then the resulting induction is called the compact induction.
infinitesimally
Two admissible representations of a real reductive group are said to be infinitesimally equivalent if their associated Lie algebra representations on the space of K-finite vectors are isomorphic.
integrable
A representation of a Kac–Moody algebra is said to be integrable if (1) it is a sum of weight spaces and (2) Chevalley generators are locally nilpotent.
intertwining
The term "intertwining operator" is an old name for a G-linear map between representations.
involution
An involution representation is a representation of a C*-algebra on a Hilbert space that preserves involution.
irreducible
An irreducible representation is a representation whose only subrepresentations are zero and itself. The term "irreducible" is synonymous with "simple".
isomorphism
An isomorphism between representations of a group G is an invertible G-linear map between the representations.
isotypic
1.Given a representation V and a simple representation W (subrepresebtation or otherwise), the isotypic component of V of type W is the direct sum of all subrepresentations of V that are isomorphic to W. For example, let A be a ring and G a group acting on it as automorphisms. If A is semisimple as a G-module, then the ring of invariants is the isotypic component of A of trivial type.
2.The isotypic decomposition of a semisimple representation is the decomposition into the isotypic components.
Maschke's theorem states that a finite-dimensional representation over a field F of a finite group G is a semisimple representation if the characteristic of F does not divide the order of G.
Mackey theory
The Mackey theory may be thought of a tool to answer the question: given a representation W of a subgroup H of a group G, when is the induced representation an irreducible representation of G?[1]
A matrix coefficient of a representation is a linear combination of functions on G of the form for v in V and in the dual space . Note the notion makes sense for any group: if G is a topological group and is continuous, then a matrix matrix coefficient would be a continuous function on G. If G and are algebraic, it would be a regular function on G.
Given a finite-dimensional complex representation V of a finite group G, Molien's theorem says that the series , where denotes the space of -invariant homogeneous polynomials on V of degree n, coincides with . The theorem is also valid for a reductive group by replacing by integration over a maximal compact subgroup.
Given a group G, a G-set X and V the vector space of functions from X to a fixed field, a permutation representation of G on V is a representation given by the induced action of G on V; i.e., . For example, if X is a finite set and V is viewed as a vector space with a basis parameteized by X, then the symmetric group permutates the elements of the basis and its linear extension is precisely the permutation representation.
The term "primitive element" (or a vector) is an old term for a Borel-weight vector.
projective
A projective representation of a group G is a group homomorphism . Since , a projective representation is precisely a group action of G on as automorphisms.
proper
A proper subrepresentation of a representation V is a subrepresentstion that is not V.
quotient
Given a representation V and a subrepresentation , the quotient representation is the representation given by .
Representation theory is simple to define: it is the study of the ways in which a given group may act on vector spaces. It is almost certainly unique, however, among such clearly delineated subjects, in the breadth of its interest to mathematicians. This is not surprising: group actions are ubiquitous in 20th century mathematics, and where the object on which a group acts is not a vector space, we have learned to replace it by one that is (e.g., a cohomology group, tangent space, etc.). As a consequence, many mathematicians other than specialists in the field (or even those who think they might want to be) come in contact with the subject in various ways.
Fulton, William; Harris, Joe, Representation Theory: A First Course
A linear representation of a group G is a group homomorphism from G to the general linear group. Depending on the group G, the homomorphism is often implicitly required to be a morphishm in a category to which G belongs; e.g., if G is a topological group, then must be continuous. The adjective “linear” is often omitted.
2.Equivalently, a linear representation is a group action of G on a vector space V that is linear: the action such that for each g in G, is a linear transformation.
3.A virtual representation is an element of the Grothendieck ring of the category of representations.
2.Schur's lemma states that a G-linear map between irreducible representations must be either bijective or zero.
3.The Schur orthogonality relations on a compact group says the characters of non-isomorphic irreducible representations are orthogonal to each other.
4.The Schur functor constructs representations such as symmetric powers or exterior powers according to a partition . The characters of are Schur polynomials.
5.The Schur–Weyl duality computes the irreducible representations occurring in tensor powers of -modules.
A semisimple representation (also called a completely reducible representation) is a direct sum of simple representations.
simple
Another term for "irreducible".
smooth
1.A smooth representation of a locally profinite groupG is a complex representation such that, for each v in V, there is some compact open subgroup K of G that fixes v; i.e., for every g in K.
2.A smooth vector in a representation space of a Lie group is a vector v such that is a smooth function.
2.A unitarizable representation is a representation equivalent to a unitary representation.
Verma module
Given a complex semisimple Lie algebra , a Cartan subalgebra and a choice of a positive Weyl chamber, the Verma module associated to a linear functional :{\mathfrak {h}}\to \mathbb {C} }
is the quotient of the enveloping algebra by the left ideal generated by for all positive roots as well as for all .[3]
weight
1.The term "weight" is another name for a character.
2.The weight subspace of a representation V of a weight is the subspace that has positive dimension.
3.Similarly, for a linear functional :{\mathfrak {h}}\to \mathbb {C} }
of a complex Lie algebra , is a weight of an -module V if has positive dimension; cf. #highest weight.
4.weight lattice
5.dominant weight: a weight \lambda is dominant if for some
6.fundamental dominant weight:: Given a set of simple roots , it is a basis of . is a basis of too; the dual basis defined by , is called the fundamental dominant weights.
3.The Weyl integration formula says: given a compact connected Lie group G with a maximal torus T, there exists a real continuous function u on T such that for every continuous function f on G,
(Explicitly, is 1 over the cardinality of the Weyl group times the product of over the roots .)
2.The Young symmetrizer is the G-linear endomorphism of a tensor power of a G-module V defined according to a given partition . By definition, the Schur functor of a representation V assigns to V the image of .
zero
A zero representation is a zero-dimensional representation. Note: while a zero representation is a trivial representation, a trivial representation need not be zero (since “trivial” mean G acts trivially.)
Editorial note: this is the definition in (Humphreys 1972, § 20.3.) as well as (Gaitsgory 2005, § 1.2.) and differs from the original by half the sum of the positive roots.
Adams, J. F. (1969), Lectures on Lie Groups, University of Chicago Press
Theodor Bröcker and Tammo tom Dieck, Representations of compact Lie groups, Graduate Texts in Mathematics 98, Springer-Verlag, Berlin, 1995.
Knapp, Anthony W. (2001), Representation theory of semisimple groups. An overview based on examples., Princeton Landmarks in Mathematics, Princeton University Press, ISBN978-0-691-09089-4
N. Wallach, Real Reductive Groups, 2 vols., Academic Press 1988,
M. Duflo et M. Vergne, La formule de Plancherel des groupes de Lie semi-simples réels, in “Representations of Lie Groups;” Kyoto, Hiroshima (1986), Advanced Studies in Pure Mathematics 14, 1988.