Zakai equation

In a field of mathematics known as differential geometry, a Courant algebroid is a structure which, in a certain sense, blends the concepts of Lie algebroid and of quadratic Lie algebra. This notion, which plays a fundamental role in the study of Hitchin's generalized complex structures, was originally introduced by Zhang-Ju Liu, Alan Weinstein and Ping Xu in their investigation of doubles of Lie bialgebroids in 1997.^[1] Liu, Weinstein and Xu named it after Courant, who had implicitly devised earlier in 1990^[2] the standard prototype of Courant algebroid through his discovery of a skew symmetric bracket on ${\displaystyle TM\oplus T^{*}M}$, called Courant bracket today, which fails to satisfy the Jacobi identity. Both this standard example and the double of a Lie bialgebra are special instances of Courant algebroids.

Definition

A Courant algebroid consists of the data a vector bundle ${\displaystyle E\to M}$ with a bracket ${\displaystyle [.,.]:\mathrm{\Gamma }E\times \mathrm{\Gamma }E\to \mathrm{\Gamma }E}$, a non degenerate fiber-wise inner product ${\displaystyle ⟨.,.⟩:E\times E\to M\times \mathbb{ℝ}}$, and a bundle map ${\displaystyle \rho :E\to TM}$ subject to the following axioms,

${\displaystyle [\varphi ,[\chi ,\psi ]]=[[\varphi ,\chi ],\psi ]+[\chi ,[\varphi ,\psi ]]}$

${\displaystyle [\varphi ,f\psi ]=\rho (\varphi )f\psi +f[\varphi ,\psi ]}$

${\displaystyle [\varphi ,\varphi ]=\frac{1}{2}D⟨\varphi ,\varphi ⟩}$

${\displaystyle \rho (\varphi )⟨\psi ,\psi ⟩=2⟨[\varphi ,\psi ],\psi ⟩}$

where φ,ψ,χ are sections of E and f is a smooth function on the base manifold M. D is the combination ${\displaystyle {\kappa }^{-1}{\rho }^{T}d}$ with d the de Rham differential, ${\displaystyle {\rho }^T}$ the dual map of ${\displaystyle \rho }$, and κ the map from E to ${\displaystyle E^{*}}$ induced by the inner product.

Properties

The bracket is not skew-symmetric as one can see from the third axiom. Instead it fulfills a certain Jacobi-identity (first axiom) and a Leibniz rule (second axiom). From these two axioms one can derive that the anchor map ρ is a morphism of brackets:

${\displaystyle \rho [\varphi ,\psi ]=[\rho (\varphi ),\rho (\psi )].}$

The fourth rule is an invariance of the inner product under the bracket. Polarization leads to

${\displaystyle \rho (\varphi )⟨\chi ,\psi ⟩=⟨[\varphi ,\chi ],\psi ⟩+⟨\chi ,[\varphi ,\psi ]⟩.}$

Examples

An example of the Courant algebroid is the Dorfman bracket^[3] on the direct sum ${\displaystyle TM\oplus T^{*}M}$ with a twist introduced by Ševera,^[4] (1998) defined as:

${\displaystyle [X+\xi ,Y+\eta ]=[X,Y]+({\mathcal{ℒ}}_X\eta -i(Y)d\xi +i(X)i(Y)H)}$

where X,Y are vector fields, ξ,η are 1-forms and H is a closed 3-form twisting the bracket. This bracket is used to describe the integrability of generalized complex structures.

A more general example arises from a Lie algebroid A whose induced differential on ${\displaystyle A^{*}}$ will be written as d again. Then use the same formula as for the Dorfman bracket with H an A-3-form closed under d.

Another example of a Courant algebroid is a quadratic Lie algebra, i.e. a Lie algebra with an invariant scalar product. Here the base manifold is just a point and thus the anchor map (and D) are trivial.

The example described in the paper by Weinstein et al. comes from a Lie bialgebroid, i.e. A a Lie algebroid (with anchor ${\displaystyle {\rho }_A}$ and bracket ${\displaystyle [.,.{]}_A}$), also its dual ${\displaystyle A^{*}}$ a Lie algebroid (inducing the differential ${\displaystyle d_{A^{*}}}$ on ${\displaystyle {\wedge }^{*}A}$) and ${\displaystyle d_{A^{*}}[X,Y{]}_A=[d_{A^{*}}X,Y{]}_A+[X,d_{A^{*}}Y{]}_A}$ (where on the RHS you extend the A-bracket to ${\displaystyle {\wedge }^{*}A}$ using graded Leibniz rule). This notion is symmetric in A and ${\displaystyle A^{*}}$ (see Roytenberg). Here ${\displaystyle E=A\oplus A^{*}}$ with anchor ${\displaystyle \rho (X+\alpha )={\rho }_A(X)+{\rho }_{A^{*}}(\alpha )}$ and the bracket is the skew-symmetrization of the above in X and α (equivalently in Y and β):

${\displaystyle [X+\alpha ,Y+\beta ]=([X,Y{]}_A+{\mathcal{ℒ}}_{\alpha }^{A^{*}}Y-i_{\beta }{d}_{A^{*}}X)+([\alpha ,\beta {]}_{A^{*}}+{\mathcal{ℒ}}_X^A\beta -i_Y{d}_A\alpha )}$

Skew-symmetric bracket

Instead of the definition above one can introduce a skew-symmetric bracket as

${\displaystyle [[\varphi ,\psi ]]=\frac{1}{2}([\varphi ,\psi ]-[\psi ,\varphi ])}$

This fulfills a homotopic Jacobi-identity.

${\displaystyle [[\varphi ,[[\psi ,\chi ]]]]+\text{cycl.}=DT(\varphi ,\psi ,\chi )}$

where T is

${\displaystyle T(\varphi ,\psi ,\chi )=\frac{1}{3}⟨[\varphi ,\psi ],\chi ⟩+\text{cycl.}}$

The Leibniz rule and the invariance of the scalar product become modified by the relation ${\displaystyle [[\varphi ,\psi ]]=[\varphi ,\psi ]-\frac{1}{2}D⟨\varphi ,\psi ⟩}$ and the violation of skew-symmetry gets replaced by the axiom

${\displaystyle \rho \circ D=0}$

The skew-symmetric bracket together with the derivation D and the Jacobiator T form a strongly homotopic Lie algebra.

Dirac structures

Given a Courant algebroid with the inner product ${\displaystyle ⟨.,.⟩}$ of split signature (e.g. the standard one ${\displaystyle TM\oplus T^{*}M}$), then a Dirac structure is a maximally isotropic integrable vector subbundle L → M, i.e.

${\displaystyle ⟨L,L⟩\equiv 0}$,

${\displaystyle \mathrm{r}\mathrm{k}L=\frac{1}{2}\mathrm{r}\mathrm{k}E}$,

${\displaystyle [\mathrm{\Gamma }L,\mathrm{\Gamma }L]\subset \mathrm{\Gamma }L}$.

Examples

As discovered by Courant and parallel by Dorfman, the graph of a 2-form ω ∈ Ω²(M) is maximally isotropic and moreover integrable iff dω = 0, i.e. the 2-form is closed under the de Rham differential, i.e. a presymplectic structure.

A second class of examples arises from bivectors ${\displaystyle \mathrm{\Pi }\in \mathrm{\Gamma }({\wedge }^{2}TM)}$ whose graph is maximally isotropic and integrable iff [Π,Π] = 0, i.e. Π is a Poisson bivector on M.

Generalized complex structures

(see also the main article generalized complex geometry)

Given a Courant algebroid with inner product of split signature. A generalized complex structure L → M is a Dirac structure in the complexified Courant algebroid with the additional property

${\displaystyle L\cap \overline{L}=0}$

where ${\displaystyle \overline{}}$ means complex conjugation with respect to the standard complex structure on the complexification.

As studied in detail by Gualtieri^[5] the generalized complex structures permit the study of geometry analogous to complex geometry.

Examples

Examples are beside presymplectic and Poisson structures also the graph of a complex structure J: TM → TM.

References

• Dmitry Roytenberg: Courant algebroids, derived brackets, and even symplectic supermanifolds, PhD thesis Univ. of California Berkeley (1999)