nLab symplectic manifold

Redirected from "symplectic forms".

Contents

Context

Symplectic geometry

Definition
Properties

Darboux coordinates
Relation to almost symplectic structure
Relation to almost Hermitian and Kähler structure
Symplectomorphisms
Poisson structure

Examples
Related concepts
References

Definition

A symplectic manifold is

a smooth manifold $X$ of even dimension $dim X = 2 n$ ;
equipped with a symplectic form:
- a closed smooth 2-form $\omega \in \Omega^2_{cl}(X)$ ;
- such that $\omega$ is non-degenerate, which means equivalently that
  - $\omega^{\wedge n}=\omega\wedge\omega\wedge\cdots\wedge\omega$ has the maximal rank at every point $p\in X$ ;
  - $(\wedge^2 T^*_p X,\omega_p)$ is a symplectic vector space for every point $p\in X$ .

Definition

A real symplectic manifold $X$ is

a $2n$ -dimensional topological manifold
equipped with a symplectic atlas:
- an atlas consisting of smooth charts $\phi_i:U_i\to X$ as usual,
- such that the transition functions $\phi_j^{-1}\circ\phi_i:\phi_i^{-1}(\phi_i(U_i)\cap\phi_j(U_j))\to \phi_j^{-1}(\phi_i(U_i)\cap\phi_j(U_j))$ preserve the standard symplectic form $\omega_0=\sum_{i=1}^n dx_i\wedge dp_i$ on $\mathbb{R}^{2n}$ with the basis $(x_1,\ldots,x_n,p_1,\ldots,p_n)$ .

Remark

The non-degeneracy of the symplectic form implies that it defines an isomorphism

\omega(-,-) : \Gamma(T X) \to \Gamma(T^* X)

between sections of the tangent bundle – vector fields – and sections of the cotangent bundle – differential 1-forms – on $X$ by the map

(v \in T_x X) \mapsto (\omega(v,-) \in T^*_x X) \,.

Definition

The vector fields in the image of the exact 1-forms under the isomorphism, remark , are called Hamiltonian vector fields.

This means that for $H \in C^\infty(X)$ a smooth function and $d H$ its differential 1-form, the corresponding Hamiltonian vector field $v_H \in \Gamma(T X)$ is the unique vector field such that

d H = \omega(v_H, -) \,

Equivalently, for $\phi : \mathbb{R}^{2n} \to X$ a coordinate chart of $X$ and $\phi^*\omega = \omega_{i j} d x^i \wedge d x^j$ the symplectic form on this patch, the Hamiltonian vector field $v_H$ is

v_H = \frac{\partial H}{\partial x^i} (\omega^{-1})^{i j} \partial_j \,.

Properties

Darboux coordinates

By Darboux's theorem every symplectic manifold has an atlas by coordinate charts $\mathbb{R}^{2n} \simeq U \hookrightarrow X$ on which the symplectic form takes the canonical form $\omega|_U = \sum_{k = 1}^n d x^{2k} \wedge d x^{2 k+1}$ .

Relation to almost symplectic structure

The existence of a 2-form $\omega \in \Omega^2(X)$ which is non-degenerate (but not necessarily closed) is equivalent to the existence of a Sp-structure on $X$ , a reduction of the structure group of the tangent bundle along the inclusion of the symplectic group into the general linear group

Sp(2n) \hookrightarrow GL(2n) \,.

Such an Sp(2n)-structure is also called an almost symplectic structure on $X$ . Adding the extra condition that $d \omega = 0$ – the condition for integrability of G-structures – makes it a genuine symplectic structure. See at integrability of G-structures – Examples – Symplectic structure.

A metaplectic structure on a symplectic or almost symplectic manifold is in turn lift of the structure group to the metaplectic group.

Relation to almost Hermitian and Kähler structure

By the above, a symplectic manifold structure is an integrable $Sp(2n,\mathbb{R}) \hookrightarrow GL(2n,\mathbb{R})$ -structure. Further reduction of the structure group along the maximal compact subgroup inclusion of the unitary group $U(n) \hookrightarrow Sp(2n,\mathbb{R})$ yields is an almost Hermitian structure. If that is again first order integrable then it is Kähler structure.

Such a refinement from symplectic to Kähler structure is also called a choice of Kähler polarization.

Symplectomorphisms

Proposition

For $(X, \omega)$ a symplectic manifold, the vector fields $v \in \Gamma(T X)$ that generate diffeomorphisms that preserve the symplectic structure are precisely the locally Hamiltonian vector fields.

Proof

The condition in question is that the Lie derivative

L_v \omega = 0

vanishes. By Cartan's magic formula and using that $d \omega = 0$ this is equivalently

d \iota_v \omega = 0 \,.

By the Poincare lemma it follows that there is locally a function $H$ with $d H = \iota_v \omega$ .

Poisson structure

Definition

For $(X,\omega)$ a symplectic manifold, define a bilinear skew-symmetric map

\{-,-\} : C^\infty(X) \otimes C^\infty(X) \to C^\infty(X)

\{F,H\} := \iota_{v_F} \iota_{v_H} \omega \,.

In a coordinate chart this says that

\{F,H\} = (\frac{\partial F}{\partial x^i}) (\omega^{-1})^{i j} (\frac{\partial H}{\partial x^j}) \,.

Proposition

The bracket $\{-,-\}$ makes $C^\infty(X)$ a Poisson algebra.

Examples

every Kähler manifold is canonically also a symplectic manifold;
the critical locus over any local action functional becomes a symplectic manifold after dividing out symmetries: the reduced phase space.

Related concepts

The notion of symplectic manifold is equivalent to that of symplectic Lie n-algebroid for $n = 0$ . (See there.)

type of subspace $W$ of inner product space	condition on orthogonal space $W^\perp$
isotropic subspace	$W \subset W^\perp$
coisotropic subspace	$W^\perp \subset W$
Lagrangian subspace	$W = W^\perp$	(for symplectic form)
symplectic space	$W \cap W^\perp = \{0\}$	(for symplectic form)

∞-Chern-Simons theory from binary and non-degenerate invariant polynomial

$n \in \mathbb{N}$	symplectic Lie n-algebroid	Lie integrated smooth ∞-groupoid = moduli ∞-stack of fields of $(n+1)$ -d sigma-model	higher symplectic geometry	$(n+1)$ d sigma-model	dg-Lagrangian submanifold/ real polarization leaf	= brane	(n+1)-module of quantum states in codimension $(n+1)$	discussed in:
0	symplectic manifold	symplectic manifold	symplectic geometry		Lagrangian submanifold	–	ordinary space of states (in geometric quantization)	geometric quantization
1	Poisson Lie algebroid	symplectic groupoid	2-plectic geometry	Poisson sigma-model	coisotropic submanifold (of underlying Poisson manifold)	brane of Poisson sigma-model	2-module = category of modules over strict deformation quantiized algebra of observables	extended geometric quantization of 2d Chern-Simons theory
2	Courant Lie 2-algebroid	symplectic 2-groupoid	3-plectic geometry	Courant sigma-model	Dirac structure	D-brane in type II geometry
$n$	symplectic Lie n-algebroid	symplectic n-groupoid	(n+1)-plectic geometry	$d = n+1$ AKSZ sigma-model

(adapted from Ševera 00)

References

See the references at symplectic geometry.

Discussion of the torsion-invariants of almost symplectic structures includes

Rui Albuquerque, Roger Picken, On invariants of almost symplectic connections (arXiv:1107.1860)

The generalization of the notion of symplectic manifolds to dg-manifolds is sometimes known as PQ-supermanifolds , due to

M. Alexandrov, M. Kontsevich, A. Schwarz, O. Zaboronsky, The geometry of the master equation and topological quantum field theory, Int. J. Modern Phys. A 12(7):1405–1429, 1997 (arXiv:hep-th/9502010)

On symplectic orbifolds:

Misha Verbitsky, Holomorphic symplectic geometry and orbifold singularities, Asian J. Math. 4 (2000), no. 3, 553-563 (arXiv:math/9903175)

On a proposal for homotopy theory of symplectic manifolds:

Vardan Oganesyan, The first step towards symplectic homotopy theory [arXiv:2304.10529]

Last revised on July 18, 2024 at 12:55:56. See the history of this page for a list of all contributions to it.

nLab symplectic manifold

Context

Symplectic geometry

Background

Basic concepts

Classical mechanics and quantization

Contents

Definition

Definition

Definition

Remark

Definition

Properties

Darboux coordinates

Relation to almost symplectic structure

Relation to almost Hermitian and Kähler structure

Symplectomorphisms

Proposition

Proof

Poisson structure

Definition

Proposition

Examples

Related concepts

References