Momentum map explained

In mathematics, specifically in symplectic geometry, the momentum map (or, by false etymology, moment map^[1]) is a tool associated with a Hamiltonian action of a Lie group on a symplectic manifold, used to construct conserved quantities for the action. The momentum map generalizes the classical notions of linear and angular momentum. It is an essential ingredient in various constructions of symplectic manifolds, including symplectic (Marsden–Weinstein) quotients, discussed below, and symplectic cuts and sums.

Formal definition

Let

be a manifold with symplectic form \omega

. Suppose that a Lie group G

acts on M

via symplectomorphisms (that is, the action of each g

in G

preserves \omega

). Let

ak{g}

be the Lie algebra of G

,

ak{g}^*

its dual, and

\langle ⋅ , ⋅ \rangle:ak{g}^* x ak{g}\toR

the pairing between the two. Any

\xi

in
ak{g}

induces a vector field

\rho(\xi)

describing the infinitesimal action of

\xi

. To be precise, at a point

the vector
\rho(\xi)_x

is

\left.	d
	dt

\right|_t\exp(t\xi) ⋅ x,

where

\exp:ak{g}\toG

is the exponential map and

⋅

denotes the G

-action on M

.^[2] Let

\iota_\rho(\xi)\omega

denote the contraction of this vector field with \omega

. Because G

acts by symplectomorphisms, it follows that

\iota_\rho(\xi)\omega

is closed (for all \xi

in

ak{g}

Suppose that

\iota_\rho(\xi)\omega

is not just closed but also exact, so that

\iota_\rho(\xi)\omega =dH_\xi

for some function

H_\xi:M\toR

. If this holds, then one may choose the

H_\xi

to make the map

\xi\mapstoH_\xi

linear. A momentum map for the G

-action on

(M,\omega)

is a map

\mu:M\toak{g}^*

such that

d(\langle\mu,\xi\rangle)=\iota_\rho(\xi)\omega

for all

\xi

in
ak{g}

. Here
\langle\mu,\xi\rangle

is the function from

to R

defined by
\langle\mu,\xi\rangle(x)=\langle\mu(x),\xi\rangle

. The momentum map is uniquely defined up to an additive constant of integration (on each connected component).

-action on a symplectic manifold

(M,\omega)

is called Hamiltonian if it is symplectic and if there exists a momentum map.

A momentum map is often also required to be

-equivariant, where G

acts on
ak{g}^*

via the coadjoint action, and sometimes this requirement is included in the definition of a Hamiltonian group action. If the group is compact or semisimple, then the constant of integration can always be chosen to make the momentum map coadjoint equivariant. However, in general the coadjoint action must be modified to make the map equivariant (this is the case for example for the Euclidean group). The modification is by a 1-cocycle on the group with values in
ak{g}^*

, as first described by Souriau (1970).

Examples of momentum maps

In the case of a Hamiltonian action of the circle

G=U(1)

, the Lie algebra dual

ak{g}^*

is naturally identified with

, and the momentum map is simply the Hamiltonian function that generates the circle action.

Another classical case occurs when

is the cotangent bundle of

R³

and

is the Euclidean group generated by rotations and translations. That is,

is a six-dimensional group, the semidirect product of

\operatorname{SO}(3)

and

R³

. The six components of the momentum map are then the three angular momenta and the three linear momenta.

Let

be a smooth manifold and let

T^*N

be its cotangent bundle, with projection map

\pi:T^*N → N

. Let

\tau

denote the tautological 1-form on

T^*N

. Suppose

acts on

. The induced action of

on the symplectic manifold

(T^*N,d\tau)

, given by

g ⋅ η:=(T_\pi(η)g^-1)^*η

for

g\inG,η\inT^*N

is Hamiltonian with momentum map

-\iota_\rho(\xi)\tau

for all

\xi\inak{g}

. Here

\iota_\rho(\xi)\tau

denotes the contraction of the vector field

\rho(\xi)

, the infinitesimal action of

\xi

, with the 1-form

\tau

The facts mentioned below may be used to generate more examples of momentum maps.

Some facts about momentum maps

Let

G,H

be Lie groups with Lie algebras

ak{g},ak{h}

, respectively.

l{O}(F),F\inak{g}^*

be a coadjoint orbit. Then there exists a unique symplectic structure on

l{O}(F)

such that inclusion map

l{O}(F)\hookrightarrowak{g}^*

is a momentum map.

act on a symplectic manifold

(M,\omega)

with

\Phi_G:M → ak{g}^*

a momentum map for the action, and

\psi:H → G

be a Lie group homomorphism, inducing an action of

. Then the action of

is also Hamiltonian, with momentum map given by

	*
(d\psi)
	e

\circ\Phi_G

, where

	*
(d\psi)
	e

:ak{g}^* → ak{h}^*

is the dual map to

(d\psi)_e:ak{h} → ak{g}

(

denotes the identity element of

). A case of special interest is when

is a Lie subgroup of

and

\psi

is the inclusion map.

(M_1,\omega₁₎

be a Hamiltonian

-manifold and

(M_2,\omega₂₎

a Hamiltonian

-manifold. Then the natural action of

G x H

(M₁ x M_2,\omega₁ x \omega₂₎

is Hamiltonian, with momentum map the direct sum of the two momentum maps

\Phi_G

and

\Phi_H

. Here

\omega₁ x \omega₂:=

	*\omega
\pi
	1

	*\omega
\pi
	2

, where

\pi_i:M₁ x M₂ → M_i

denotes the projection map.

be a Hamiltonian

-manifold, and

a submanifold of

invariant under

such that the restriction of the symplectic form on

is non-degenerate. This imparts a symplectic structure to

in a natural way. Then the action of

is also Hamiltonian, with momentum map the composition of the inclusion map with

's momentum map.

Symplectic quotients

Suppose that the action of a Lie group

on the symplectic manifold
(M,\omega)

is Hamiltonian, as defined above, with equivariant momentum map
\mu:M\toak{g}^*

. From the Hamiltonian condition, it follows that
\mu^-1(0)

is invariant under

Assume now that

acts freely and properly on
\mu^-1(0)

. It follows that

is a regular value of
\mu

, so
\mu^-1(0)

and its quotient
\mu^-1(0)/G

are both smooth manifolds. The quotient inherits a symplectic form from

; that is, there is a unique symplectic form on the quotient whose pullback to
\mu^-1(0)

equals the restriction of

\omega

to
\mu^-1(0)

. Thus, the quotient is a symplectic manifold, called the Marsden–Weinstein quotient, after, symplectic quotient, or symplectic reduction of

and is denoted
M//G

. Its dimension equals the dimension of

minus twice the dimension of

More generally, if G does not act freely (but still properly), then showed that

M//G=\mu^-1(0)/G

is a stratified symplectic space, i.e. a stratified space with compatible symplectic structures on the strata.

Flat connections on a surface

The space

\Omega^1(\Sigma,ak{g})

of connections on the trivial bundle

\Sigma x G

on a surface carries an infinite dimensional symplectic form

\langle\alpha,\beta\rangle:=\int_\Sigmatr(\alpha\wedge\beta).

The gauge group

l{G}=Map(\Sigma,G)

acts on connections by conjugation

g ⋅ A:=g^-1(dg)+g^-1Ag

. Identify

Lie(l{G})=\Omega^0(\Sigma,ak{g})=\Omega^2(\Sigma,ak{g})^*

via the integration pairing. Then the map

\mu:\Omega^1(\Sigma,ak{g}) → \Omega^2(\Sigma,ak{g}), A \mapsto F:=dA+

	1
	2

[A\wedgeA]

that sends a connection to its curvature is a moment map for the action of the gauge group on connections. In particular the moduli space of flat connections modulo gauge equivalence

\mu^-1(0)/l{G}=\Omega^1(\Sigma,ak{g})//l{G}

is given by symplectic reduction.

References

J.-M. Souriau, Structure des systèmes dynamiques, Maîtrises de mathématiques, Dunod, Paris, 1970. .
S. K. Donaldson and P. B. Kronheimer, The Geometry of Four-Manifolds, Oxford Science Publications, 1990. .
Dusa McDuff and Dietmar Salamon, Introduction to Symplectic Topology, Oxford Science Publications, 1998. .
- Book: Ortega. Juan-Pablo. Ratiu. Tudor S.. Momentum maps and Hamiltonian reduction. Birkhauser Boston. Progress in Mathematics. 222. 2004. 0-8176-4307-9.

Notes and References

Moment map is a misnomer and physically incorrect. It is an erroneous translation of the French notion application moment. See this mathoverflow question for the history of the name.
The vector field ρ(ξ) is called sometimes the Killing vector field relative to the action of the one-parameter subgroup generated by ξ. See, for instance,

Momentum map explained

Formal definition

Examples of momentum maps

Some facts about momentum maps

Symplectic quotients

Flat connections on a surface

See also

References

Notes and References