In mathematics a Dirac structure is a geometric structure generalizing both symplectic structures and Poisson structures, and having several applications to mechanics. It is based on the notion of the Dirac bracket constraint introduced by Paul Dirac and was first introduced by Ted Courant and Alan Weinstein.

Linear Dirac structures

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Let   be a real vector space, and   its dual. A (linear) Dirac structure on   is a linear subspace   of   satisfying

  • for all   one has  ,
  •   is maximal with respect to this property.

In particular, if   is finite dimensional, then the second criterion is satisfied if  . Similar definitions can be made for vector spaces over other fields.

An alternative (equivalent) definition often used is that   satisfies  , where orthogonality is with respect to the symmetric bilinear form on   given by  .

Examples

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  1. If   is a vector subspace, then   is a Dirac structure on  , where   is the annihilator of  ; that is,  .
  2. Let   be a skew-symmetric linear map, then the graph of   is a Dirac structure.
  3. Similarly, if   is a skew-symmetric linear map, then its graph is a Dirac structure.

Dirac structures on manifolds

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A Dirac structure   on a smooth manifold   is an assignment of a (linear) Dirac structure on the tangent space to   at  , for each  . That is,

  • for each  , a Dirac subspace   of the space  .

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

  • suppose   are sections of the Dirac bundle   ( ) then  

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

Examples

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  1. Let   be a smooth distribution of constant rank on a manifold  , and for each   let  , then the union of these subspaces over   forms a Dirac structure on  .
  2. Let   be a symplectic form on a manifold  , 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   be a Poisson structure on a manifold  , then its graph is a (closed) Dirac structure.

Applications

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References

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  • H. Bursztyn, A brief introduction to Dirac manifolds. Geometric and topological methods for quantum field theory, 4–38, Cambridge Univ. Press, Cambridge, 2013.
  • Bursztyn, Henrique; Crainic, Marius (2005). "Dirac structures, momentum maps, and quasi-Poisson manifolds". The Breadth of Symplectic and Poisson Geometry. Progress in Mathematics. Vol. 232. Birkhauser-Verlag. pp. 1–40.
  • Courant, Theodore; Weinstein, Alan (1988). "Beyond Poisson structures". Séminaire sud-rhodanien de géométrie VIII. Travaux en Cours. Vol. 27. Paris: Hermann.
  • Dorfman, Irène (1993). Dirac structures and integrability of nonlinear evolution equations. Wiley.