Dirac structure

Let ${\displaystyle V}$  be a real vector space, and ${\displaystyle V^{*}}$  its dual. A (linear) Dirac structure on ${\displaystyle V}$  is a linear subspace ${\displaystyle D}$  of ${\displaystyle V\times V^{*}}$  satisfying

• for all ${\displaystyle (v,\alpha )\in D}$  one has ${\displaystyle \left\langle \alpha ,\,v\right\rangle =0}$ ,
• ${\displaystyle D}$  is maximal with respect to this property.

In particular, if ${\displaystyle V}$  is finite dimensional, then the second criterion is satisfied if ${\displaystyle \dim D=\dim V}$ . Similar definitions can be made for vector spaces over other fields.

An alternative (equivalent) definition often used is that ${\displaystyle D}$  satisfies ${\displaystyle D=D^{\perp }}$ , where orthogonality is with respect to the symmetric bilinear form on ${\displaystyle V\times V^{*}}$  given by ${\displaystyle {\bigl \langle }(u,\alpha ),\,(v,\beta ){\bigr \rangle }=\left\langle \alpha ,v\right\rangle +\left\langle \beta ,u\right\rangle }$ .

1. If ${\displaystyle U\subset V}$  is a vector subspace, then ${\displaystyle D=U\times U^{\circ }}$  is a Dirac structure on ${\displaystyle V}$ , where ${\displaystyle U^{\circ }}$  is the annihilator of ${\displaystyle U}$ ; that is, ${\displaystyle U^{\circ }=\left\{\alpha \in V^{*}\mid \alpha _{\vert U}=0\right\}}$ .
2. Let ${\displaystyle \omega :V\to V^{*}}$  be a skew-symmetric linear map, then the graph of ${\displaystyle \omega }$  is a Dirac structure.
3. Similarly, if ${\displaystyle \Pi :V^{*}\to V}$  is a skew-symmetric linear map, then its graph is a Dirac structure.

A Dirac structure ${\displaystyle {\mathfrak {D}}}$  on a smooth manifold ${\displaystyle M}$  is an assignment of a (linear) Dirac structure on the tangent space to ${\displaystyle M}$  at ${\displaystyle m}$ , for each ${\displaystyle m\in M}$ . That is,

• for each ${\displaystyle m\in M}$ , a Dirac subspace ${\displaystyle D_{m}}$  of the space ${\displaystyle T_{m}M\times T_{m}^{*}M}$ .

Many authors, in particular in geometry rather than the mechanics applications, require a Dirac structure to satisfy an extra integrability condition as follows:

• suppose ${\displaystyle (X_{i},\alpha _{i})}$  are sections of the Dirac bundle ${\displaystyle {\mathfrak {D}}\to M}$  (${\displaystyle i=1,2,3}$ ) then ${\displaystyle \left\langle L_{X_{1}}(\alpha _{2}),\,X_{3}\right\rangle +\left\langle L_{X_{2}}(\alpha _{3}),\,X_{1}\right\rangle +\left\langle L_{X_{3}}(\alpha _{1}),\,X_{2}\right\rangle =0.}$ 

In the mechanics literature this would be called a closed or integrable Dirac structure.

1. Let ${\displaystyle \Delta }$  be a smooth distribution of constant rank on a manifold ${\displaystyle M}$ , and for each ${\displaystyle m\in M}$  let ${\displaystyle D_{m}=\{(u,\alpha )\in T_{m}M\times T_{m}^{*}M\mid u\in \Delta (m),\,\alpha \in \Delta (m)^{\circ }\}}$ , then the union of these subspaces over ${\displaystyle m}$  forms a Dirac structure on ${\displaystyle M}$ .
2. Let ${\displaystyle \omega }$  be a symplectic form on a manifold ${\displaystyle M}$ , then its graph is a (closed) Dirac structure. More generally, this is true for any closed 2-form. If the 2-form is not closed, then the resulting Dirac structure is not closed.
3. Let ${\displaystyle \Pi }$  be a Poisson structure on a manifold ${\displaystyle M}$ , then its graph is a (closed) Dirac structure.

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