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Symplectic cut

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In mathematics, specifically in symplectic geometry, the symplectic cut is a geometric modification on symplectic manifolds. Its effect is to decompose a given manifold into two pieces. There is an inverse operation, the symplectic sum, that glues two manifolds together into one. The symplectic cut can also be viewed as a generalization of symplectic blow up. The cut was introduced in 1995 by Eugene Lerman, who used it to study the symplectic quotient and other operations on manifolds.

Topological description

Let ( X , ω ) {\displaystyle (X,\omega )} be any symplectic manifold and

μ : X R {\displaystyle \mu :X\to \mathbb {R} }

a Hamiltonian on X {\displaystyle X} . Let ϵ {\displaystyle \epsilon } be any regular value of μ {\displaystyle \mu } , so that the level set μ 1 ( ϵ ) {\displaystyle \mu ^{-1}(\epsilon )} is a smooth manifold. Assume furthermore that μ 1 ( ϵ ) {\displaystyle \mu ^{-1}(\epsilon )} is fibered in circles, each of which is an integral curve of the induced Hamiltonian vector field.

Under these assumptions, μ 1 ( [ ϵ , ) ) {\displaystyle \mu ^{-1}([\epsilon ,\infty ))} is a manifold with boundary μ 1 ( ϵ ) {\displaystyle \mu ^{-1}(\epsilon )} , and one can form a manifold

X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }}

by collapsing each circle fiber to a point. In other words, X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }} is X {\displaystyle X} with the subset μ 1 ( ( , ϵ ) ) {\displaystyle \mu ^{-1}((-\infty ,\epsilon ))} removed and the boundary collapsed along each circle fiber. The quotient of the boundary is a submanifold of X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }} of codimension two, denoted V {\displaystyle V} .

Similarly, one may form from μ 1 ( ( , ϵ ] ) {\displaystyle \mu ^{-1}((-\infty ,\epsilon ])} a manifold X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \leq \epsilon }} , which also contains a copy of V {\displaystyle V} . The symplectic cut is the pair of manifolds X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \leq \epsilon }} and X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }} .

Sometimes it is useful to view the two halves of the symplectic cut as being joined along their shared submanifold V {\displaystyle V} to produce a singular space

X ¯ μ ϵ V X ¯ μ ϵ . {\displaystyle {\overline {X}}_{\mu \leq \epsilon }\cup _{V}{\overline {X}}_{\mu \geq \epsilon }.}

For example, this singular space is the central fiber in the symplectic sum regarded as a deformation.

Symplectic description

The preceding description is rather crude; more care is required to keep track of the symplectic structure on the symplectic cut. For this, let ( X , ω ) {\displaystyle (X,\omega )} be any symplectic manifold. Assume that the circle group U ( 1 ) {\displaystyle U(1)} acts on X {\displaystyle X} in a Hamiltonian way with moment map

μ : X R . {\displaystyle \mu :X\to \mathbb {R} .}

This moment map can be viewed as a Hamiltonian function that generates the circle action. The product space X × C {\displaystyle X\times \mathbb {C} } , with coordinate z {\displaystyle z} on C {\displaystyle \mathbb {C} } , comes with an induced symplectic form

ω ( i d z d z ¯ ) . {\displaystyle \omega \oplus (-idz\wedge d{\bar {z}}).}

The group U ( 1 ) {\displaystyle U(1)} acts on the product in a Hamiltonian way by

e i θ ( x , z ) = ( e i θ x , e i θ z ) {\displaystyle e^{i\theta }\cdot (x,z)=(e^{i\theta }\cdot x,e^{-i\theta }z)}

with moment map

ν ( x , z ) = μ ( x ) | z | 2 . {\displaystyle \nu (x,z)=\mu (x)-|z|^{2}.}

Let ϵ {\displaystyle \epsilon } be any real number such that the circle action is free on μ 1 ( ϵ ) {\displaystyle \mu ^{-1}(\epsilon )} . Then ϵ {\displaystyle \epsilon } is a regular value of ν {\displaystyle \nu } , and ν 1 ( ϵ ) {\displaystyle \nu ^{-1}(\epsilon )} is a manifold.

This manifold ν 1 ( ϵ ) {\displaystyle \nu ^{-1}(\epsilon )} contains as a submanifold the set of points ( x , z ) {\displaystyle (x,z)} with μ ( x ) = ϵ {\displaystyle \mu (x)=\epsilon } and | z | 2 = 0 {\displaystyle |z|^{2}=0} ; this submanifold is naturally identified with μ 1 ( ϵ ) {\displaystyle \mu ^{-1}(\epsilon )} . The complement of the submanifold, which consists of points ( x , z ) {\displaystyle (x,z)} with μ ( x ) > ϵ {\displaystyle \mu (x)>\epsilon } , is naturally identified with the product of

X > ϵ := μ 1 ( ( ϵ , ) ) {\displaystyle X_{>\epsilon }:=\mu ^{-1}((\epsilon ,\infty ))}

and the circle.

The manifold ν 1 ( ϵ ) {\displaystyle \nu ^{-1}(\epsilon )} inherits the Hamiltonian circle action, as do its two submanifolds just described. So one may form the symplectic quotient

X ¯ μ ϵ := ν 1 ( ϵ ) / U ( 1 ) . {\displaystyle {\overline {X}}_{\mu \geq \epsilon }:=\nu ^{-1}(\epsilon )/U(1).}

By construction, it contains X μ > ϵ {\displaystyle X_{\mu >\epsilon }} as a dense open submanifold; essentially, it compactifies this open manifold with the symplectic quotient

V := μ 1 ( ϵ ) / U ( 1 ) , {\displaystyle V:=\mu ^{-1}(\epsilon )/U(1),}

which is a symplectic submanifold of X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }} of codimension two.

If X {\displaystyle X} is Kähler, then so is the cut space X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }} ; however, the embedding of X μ > ϵ {\displaystyle X_{\mu >\epsilon }} is not an isometry.

One constructs X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \leq \epsilon }} , the other half of the symplectic cut, in a symmetric manner. The normal bundles of V {\displaystyle V} in the two halves of the cut are opposite each other (meaning symplectically anti-isomorphic). The symplectic sum of X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \geq \epsilon }} and X ¯ μ ϵ {\displaystyle {\overline {X}}_{\mu \leq \epsilon }} along V {\displaystyle V} recovers X {\displaystyle X} .

The existence of a global Hamiltonian circle action on X {\displaystyle X} appears to be a restrictive assumption. However, it is not actually necessary; the cut can be performed under more general hypotheses, such as a local Hamiltonian circle action near μ 1 ( ϵ ) {\displaystyle \mu ^{-1}(\epsilon )} (since the cut is a local operation).

Blow up as cut

When a complex manifold X {\displaystyle X} is blown up along a submanifold Z {\displaystyle Z} , the blow up locus Z {\displaystyle Z} is replaced by an exceptional divisor E {\displaystyle E} and the rest of the manifold is left undisturbed. Topologically, this operation may also be viewed as the removal of an ϵ {\displaystyle \epsilon } -neighborhood of the blow up locus, followed by the collapse of the boundary by the Hopf map.

Blowing up a symplectic manifold is more subtle, since the symplectic form must be adjusted in a neighborhood of the blow up locus in order to continue smoothly across the exceptional divisor in the blow up. The symplectic cut is an elegant means of making the neighborhood-deletion/boundary-collapse process symplectically rigorous.

As before, let ( X , ω ) {\displaystyle (X,\omega )} be a symplectic manifold with a Hamiltonian U ( 1 ) {\displaystyle U(1)} -action with moment map μ {\displaystyle \mu } . Assume that the moment map is proper and that it achieves its maximum m {\displaystyle m} exactly along a symplectic submanifold Z {\displaystyle Z} of X {\displaystyle X} . Assume furthermore that the weights of the isotropy representation of U ( 1 ) {\displaystyle U(1)} on the normal bundle N X Z {\displaystyle N_{X}Z} are all 1 {\displaystyle 1} .

Then for small ϵ {\displaystyle \epsilon } the only critical points in X μ > m ϵ {\displaystyle X_{\mu >m-\epsilon }} are those on Z {\displaystyle Z} . The symplectic cut X ¯ μ m ϵ {\displaystyle {\overline {X}}_{\mu \leq m-\epsilon }} , which is formed by deleting a symplectic ϵ {\displaystyle \epsilon } -neighborhood of Z {\displaystyle Z} and collapsing the boundary, is then the symplectic blow up of X {\displaystyle X} along Z {\displaystyle Z} .

References

  • Eugene Lerman: Symplectic cuts, Mathematical Research Letters 2 (1995), 247–258
  • Dusa McDuff and D. Salamon: Introduction to Symplectic Topology (1998) Oxford Mathematical Monographs, ISBN 0-19-850451-9.
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