When first defining (or, rather, recalling the definition of) Lie algebras I mentioned that the bracket makes each element of a Lie algebra
act by derivations on itself. We can actually say a bit more about this.First off, we need an algebra
over a field 
. This doesn’t have to be associative, as our algebras commonly are; all we need is a bilinear map 
. In particular, Lie algebras count.Now, a derivation
of is firstly a linear map from back to itself. That is, 
, where this is the algebra of endomorphisms of as a vector space over , not the endomorphisms as an algebra. Instead of preserving the multiplication, we impose the condition that behave like the product rule:
It’s easy to see that the collection
is a vector subspace, but I say that it’s actually a Lie subalgebra, when we equip the space of endomorphisms with the usual commutator bracket. That is, if and 
are two derivations, I say that their commutator is again a derivation.This, we can check:
=&\delta(\partial(ab))-\partial(\delta(ab))\\=&\delta(\partial(a)b+a\partial(b)))-\partial(\delta(a)b+a\delta(b)))\\=&\delta(\partial(a)b)+\delta(a\partial(b)))-\partial(\delta(a)b)-\partial(a\delta(b)))\\=&\delta(\partial(a))b+\partial(a)\delta(b)+\delta(a)\partial(b)+a\delta(\partial(b))\\&-\partial(\delta(a))b-\delta(a)\partial(b)-\partial(a)\delta(b)-a\partial(\delta(b))\\=&[\delta,\partial](a)b+a[\delta,\partial](b)\end{aligned}](http://s0.wp.com/latex.php?latex=%5Cdisplaystyle%5Cbegin%7Baligned%7D+%5B%5Cdelta%2C%5Cpartial%5D%28ab%29%3D%26%5Cdelta%28%5Cpartial%28ab%29%29-%5Cpartial%28%5Cdelta%28ab%29%29%5C%5C%3D%26%5Cdelta%28%5Cpartial%28a%29b%2Ba%5Cpartial%28b%29%29%29-%5Cpartial%28%5Cdelta%28a%29b%2Ba%5Cdelta%28b%29%29%29%5C%5C%3D%26%5Cdelta%28%5Cpartial%28a%29b%29%2B%5Cdelta%28a%5Cpartial%28b%29%29%29-%5Cpartial%28%5Cdelta%28a%29b%29-%5Cpartial%28a%5Cdelta%28b%29%29%29%5C%5C%3D%26%5Cdelta%28%5Cpartial%28a%29%29b%2B%5Cpartial%28a%29%5Cdelta%28b%29%2B%5Cdelta%28a%29%5Cpartial%28b%29%2Ba%5Cdelta%28%5Cpartial%28b%29%29%5C%5C%26-%5Cpartial%28%5Cdelta%28a%29%29b-%5Cdelta%28a%29%5Cpartial%28b%29-%5Cpartial%28a%29%5Cdelta%28b%29-a%5Cpartial%28%5Cdelta%28b%29%29%5C%5C%3D%26%5B%5Cdelta%2C%5Cpartial%5D%28a%29b%2Ba%5B%5Cdelta%2C%5Cpartial%5D%28b%29%5Cend%7Baligned%7D&bg=e6e6e6&fg=333333&s=0 "\displaystyle\begin{aligned} [\delta,\partial](ab)=&\delta(\partial(ab))-\partial(\delta(ab))\\=&\delta(\partial(a)b+a\partial(b)))-\partial(\delta(a)b+a\delta(b)))\\=&\delta(\partial(a)b)+\delta(a\partial(b)))-\partial(\delta(a)b)-\partial(a\delta(b)))\\=&\delta(\partial(a))b+\partial(a)\delta(b)+\delta(a)\partial(b)+a\delta(\partial(b))\\&-\partial(\delta(a))b-\delta(a)\partial(b)-\partial(a)\delta(b)-a\partial(\delta(b))\\=&[\delta,\partial](a)b+a[\delta,\partial](b)\end{aligned}")
We’ve actually seen this before. We identified the vectors at a point
on a manifold with the derivations of the (real) algebra of functions defined in a neighborhood of , so we need to take the commutator of two derivations to be sure of getting a new derivation back.So now we can say that the mapping that sends
to the endomorphism ![y\mapsto[x,y]](http://s0.wp.com/latex.php?latex=y%5Cmapsto%5Bx%2Cy%5D&bg=e6e6e6&fg=333333&s=0 "y\mapsto[x,y]")
lands in 
because of the Jacobi identity. We call this mapping 
the “adjoint representation” of , and indeed it’s actually a homomorphism of Lie algebras. That is, ![\mathrm{ad}([x,y])=[\mathrm{ad}(x),\mathrm{ad}(y)]](http://s0.wp.com/latex.php?latex=%5Cmathrm%7Bad%7D%28%5Bx%2Cy%5D%29%3D%5B%5Cmathrm%7Bad%7D%28x%29%2C%5Cmathrm%7Bad%7D%28y%29%5D&bg=e6e6e6&fg=333333&s=0 "\mathrm{ad}([x,y])=[\mathrm{ad}(x),\mathrm{ad}(y)]")
. The endomorphism on the left-hand side sends 
to ![[[x,y],z]](http://s0.wp.com/latex.php?latex=%5B%5Bx%2Cy%5D%2Cz%5D&bg=e6e6e6&fg=333333&s=0 "[[x,y],z]")
, while on the right-hand side we get ![[x,[y,z]]-[y,[x,z]]](http://s0.wp.com/latex.php?latex=%5Bx%2C%5By%2Cz%5D%5D-%5By%2C%5Bx%2Cz%5D%5D&bg=e6e6e6&fg=333333&s=0 "[x,[y,z]]-[y,[x,z]]")
. That these two are equal is yet another application of the Jacobi identity.One last piece of nomenclature: derivations in the image of
are called “inner”; all others are called “outer” derivations.
DIGITAL JUICE
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