Adjoint action of a Lie algebra on itself #
This file defines the adjoint action of a Lie algebra on itself, and establishes basic properties.
Main definitions #
LieDerivation.ad
: The adjoint action of a Lie algebraL
on itself, seen as a morphism of Lie algebras fromL
to the Lie algebra of its derivations. The adjoint action is also defined in theMathlib.Algebra.Lie.OfAssociative.lean
file, under the nameLieAlgebra.ad
, as the morphism with values in the endormophisms ofL
.
Main statements #
LieDerivation.coe_ad_apply_eq_ad_apply
: when seen as endomorphisms, both definitions coincide,LieDerivation.ad_ker_eq_center
: the kernel of the adjoint action is the center ofL
,LieDerivation.lie_der_ad_eq_ad_der
: the commutator of a derivationD
andad x
isad (D x)
,LieDerivation.ad_isIdealMorphism
: the range of the adjoint action is an ideal of the derivations.
The adjoint action of a Lie algebra L
on itself, seen as a morphism of Lie algebras from
L
to its derivations.
Note the minus sign: this is chosen to so that ad ⁅x, y⁆ = ⁅ad x, ad y⁆
.
Equations
- LieDerivation.ad R L = let __spread.0 := -LieDerivation.inner R L L; { toLinearMap := __spread.0, map_lie' := ⋯ }
Instances For
The definitions LieDerivation.ad
and LieAlgebra.ad
agree.
The kernel of the adjoint action on a Lie algebra is equal to its center.
If the center of a Lie algebra is trivial, then the adjoint action is injective.
The commutator of a derivation D
and a derivation of the form ad x
is ad (D x)
.
The range of the adjoint action homomorphism from a Lie algebra L
to the Lie algebra of its
derivations is an ideal of the latter.
A derivation D
belongs to the ideal range of the adjoint action iff it is of the form ad x
for some x
in the Lie algebra L
.