Bialgebra: Difference between revisions

In mathematics, Lie algebroids serve the same role in the theory of Lie groupoids that Lie algebras serve in the theory of Lie groups: reducing global problems to infinitesimal ones. Just as a Lie groupoid can be thought of as a "Lie group with many objects", a Lie algebroid is like a "Lie algebra with many objects".

More precisely, a Lie algebroid is a triple ${\displaystyle (E,[\cdot ,\cdot ],\rho )}$ consisting of a vector bundle ${\displaystyle E}$ over a manifold ${\displaystyle M}$, together with a Lie bracket ${\displaystyle [\cdot ,\cdot ]}$ on its module of sections ${\displaystyle \mathrm{\Gamma }(E)}$ and a morphism of vector bundles ${\displaystyle \rho :E\to TM}$ called the anchor. Here ${\displaystyle TM}$ is the tangent bundle of ${\displaystyle M}$. The anchor and the bracket are to satisfy the Leibniz rule:

${\displaystyle [X,fY]=\rho (X)f\cdot Y+f[X,Y]}$

where ${\displaystyle X,Y\in \mathrm{\Gamma }(E),f\in C^{\mathrm{\infty }}(M)}$ and ${\displaystyle \rho (X)f}$ is the derivative of ${\displaystyle f}$ along the vector field ${\displaystyle \rho (X)}$. It follows that

${\displaystyle \rho ([X,Y])=[\rho (X),\rho (Y)]}$

for all ${\displaystyle X,Y\in \mathrm{\Gamma }(E)}$.

Examples

• Every Lie algebra is a Lie algebroid over the one point manifold.

• The tangent bundle ${\displaystyle TM}$ of a manifold ${\displaystyle M}$ is a Lie algebroid for the Lie bracket of vector fields and the identity of ${\displaystyle TM}$ as an anchor.

• Every integrable subbundle of the tangent bundle — that is, one whose sections are closed under the Lie bracket — also defines a Lie algebroid.

• Every bundle of Lie algebras over a smooth manifold defines a Lie algebroid where the Lie bracket is defined pointwise and the anchor map is equal to zero.

• To every Lie groupoid is associated a Lie algebroid, generalizing how a Lie algebra is associated to a Lie group (see also below). For example, the Lie algebroid ${\displaystyle TM}$ comes from the pair groupoid whose objects are ${\displaystyle M}$, with one isomorphism between each pair of objects. Unfortunately, going back from a Lie algebroid to a Lie groupoid is not always possible,^[1] but every Lie algebroid gives a stacky Lie groupoid.^[2][3]

• Given the action of a Lie algebra g on a manifold M, the set of g -invariant vector fields on M is a Lie algebroid over the space of orbits of the action.

• The Atiyah algebroid of a principal G-bundle P over a manifold M is a Lie algebroid with short exact sequence:

  ${\displaystyle 0\to P{\times }_G\mathfrak{g}\to TP/G\stackrel{\rho }{\to }TM\to 0.}$

The space of sections of the Atiyah algebroid is the Lie algebra of G-invariant vector fields on P.

Lie algebroid associated to a Lie groupoid

To describe the construction let us fix some notation. G is the space of morphisms of the Lie groupoid, M the space of objects, ${\displaystyle e:M\to G}$ the units and ${\displaystyle t:G\to M}$ the target map.

${\displaystyle T^{t}G=\bigcup _{p\in M}T(t^{-1}(p))\subset TG}$ the t-fiber tangent space. The Lie algebroid is now the vector bundle ${\displaystyle A:=e^{*}{T}^{t}G}$. This inherits a bracket from G, because we can identify the M-sections into A with left-invariant vector fields on G. The anchor map then is obtained as the derivation of the source map ${\displaystyle Ts:e^{*}{T}^{t}G\to TM}$. Further these sections act on the smooth functions of M by identifying these with left-invariant functions on G.

As a more explicit example consider the Lie algebroid associated to the pair groupoid ${\displaystyle G:=M\times M}$. The target map is ${\displaystyle t:G\to M:(p,q)\mapsto p}$ and the units ${\displaystyle e:M\to G:p\mapsto (p,p)}$. The t-fibers are ${\displaystyle p\times M}$ and therefore ${\displaystyle T^{t}G=\bigcup _{p\in M}p\times TM\subset TM\times TM}$. So the Lie algebroid is the vector bundle ${\displaystyle A:=e^{*}{T}^{t}G=\bigcup _{p\in M}{T}_{p}M=TM}$. The extension of sections X into A to left-invariant vector fields on G is simply ${\displaystyle \tilde{X}(p,q)=0\oplus X(q)}$ and the extension of a smooth function f from M to a left-invariant function on G is ${\displaystyle \tilde{f}(p,q)=f(q)}$. Therefore the bracket on A is just the Lie bracket of tangent vector fields and the anchor map is just the identity.

Of course you could do an analog construction with the source map and right-invariant vector fields/ functions. However you get an isomorphic Lie algebroid, with the explicit isomorphism ${\displaystyle i_{*}}$, where ${\displaystyle i:G\to G}$ is the inverse map.

See also

• R-algebroid

References

External links

• Alan Weinstein, Groupoids: unifying internal and external

symmetry, AMS Notices, 43 (1996), 744-752. Also available as arXiv:math/9602220

• Kirill Mackenzie, Lie Groupoids and Lie Algebroids in Differential Geometry, Cambridge U. Press, 1987.

• Kirill Mackenzie, General Theory of Lie Groupoids and Lie Algebroids, Cambridge U. Press, 2005

• Charles-Michel Marle, Differential calculus on a Lie algebroid and Poisson manifolds (2002). Also available in arXiv:0804.2451