yep, and that exponentiates to the adjoint action of G on g
Conversation
umm okay so a lie algebroid consists of
-a vector bundle together with a lie algebra structure on its space of sections
plus some other stuff that im not gonna think about rn
this should be the lie algebra of some lie group?
1
like if i have the tangent lie algebroid on X, then the global sections give me the lie algebra of Diffeo(X), right?
umm "lie group" should be quotes there cuz it's some infinite dimensional thing but like... yah
1
if i have a lie groupoid is there some way of getting a (possibly infinite dimensional) lie group out of it?
where if i start with the smooth path groupoid i get back Diffeo(X)??
1
this construction makes me antsy, i have the sense that it's a little unnatural but i can't quite justify it 🤔
1
1
well im not sure id call it a "construction"... it's a bit under-specified
im going lie groupoid -(differentiation, a functor) -> lie algebroid -(global sections, also a functor)-> lie algebra -(integrate, not actually a well-defined operation) "lie group"
1/2
1
but it's suggestive enough that i feel like there ought to be a more direct construction to go from the lie groupoid to a lie group
otoh, i agree that this seems weird as heck
tbh im kinda just poking at the definition and saying "this seems weird"
1
Yes, there’s a way! It’s the group of bisections. See section 3.2 here: math.toronto.edu/mein/teaching/
1
2
hmmmm okay that's encouraging
it's a pretty weird seeming notion tho huh
1
2
oh nice thanks! i was getting confused because i couldn't see what group you could possibly canonically associate to an ordinary (discrete) groupoid, but i guess the group of bisections here is... the product over the wreath products of the isotropy groups
1
2
in particular it's not invariant under equivalence which is consistent with my antsiness
Yeah, that’s true. But you can get interesting things out of it, eg diffeomorphism groups, gauge groups