Representation of a Lie algebra
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In mathematics, a representation of a Lie algebra is a way of writing a Lie algebra as a set of matrices (or endomorphisms of a vector space) in such a way that the Lie bracket is given by the commutator.
The notion is closely related to that of a representation of a Lie group. Roughly speaking, the representations of Lie algebras are the differentiated form of representations of Lie groups, while the representations of the universal cover of a Lie group are the integrated form of the representations of its Lie algebra.
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[edit] Formal definition
A representation of a Lie algebra is a Lie algebra homomorphism
from to the Lie algebra of endomorphisms on a vector space V (with the commutator as the Lie bracket). Explicitly, this means that
for all x,y in . The vector space V, together with the representation ρ, is called a -module. (Many authors abuse terminology and refer to V itself as the representation).
One can equivalently define a -module as a vector space V together with a bilinear map such that
for all x,y in and v in V. This is related to the previous definition by setting
[edit] Infinitesimal Lie group representations
If is a homomorphism of Lie groups, and and are the Lie algebras of G and H respectively, then the induced map on tangent spaces is a Lie algebra homomorphism. In particular, a representation of Lie groups
determines a Lie algebra homomorphism
from to the Lie algebra of the general linear group GL(V), i.e. the endomorphism algebra of V.
A partial converse to this statement says that every representation of a finite-dimensional (real or complex) Lie algebra lifts to a unique representation of the associated simply connected Lie group, so that representations of simply-connected Lie groups are in one-to-one correspondence with representations of their Lie algebras.
[edit] Properties
Representations of a Lie algebra are in one-to-one correspondence with representations of the associated universal enveloping algebra. This follows from the universal property of that construction.
If the Lie algebra is semisimple, then all reducible representations are decomposable. Otherwise, that's not true in general.
If we have two representations, with V1 and V2 as their underlying vector spaces and ·[·]1 and ·[·]2 as the representations, then the product of both representations would have as the underlying vector space and
If L is a real Lie algebra and is a complex representation of it, we can construct another representation of L called its dual representation as follows.
Let V∗ be the dual vector space of V. In other words, V is the set of all linear maps from V to C with addition defined over it in the usual linear way, but scalar multiplication defined over it such that for any z in C, ω in V∗ and X in V. This is usually rewritten as a contraction with a sesquilinear form 〈·,·〉. i.e. 〈ω,X〉 is defined to be ω[X].
We define as follows:
- 〈A[ω],X〉 + 〈ω,A[X]〉 = 0,
for any A in L, ω in V∗ and X in V. This defines uniquely.
[edit] See also
- group representation
- representations of Lie groups
- adjoint representation of a Lie algebra
- representation of a Lie superalgebra
- representation of a Hopf algebra
- representation of an algebra
- algebra representation of a group
- algebra representation of a Lie algebra
- algebra representation of a Lie superalgebra
- algebra representation of a Hopf algebra
- unitary representation of a real Lie algebra
- unitary representation of a star Lie superalgebra.