Seiberg–Witten invariant

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In mathematics, Seiberg–Witten invariants are invariants of compact smooth 4-manifolds introduced by Witten (1994), using the Seiberg-Witten theory studied by Seiberg and Witten (1994a, 1994b) during their investigations of Seiberg-Witten gauge theory.

Seiberg-Witten invariants are similar to Donaldson invariants and can be used to prove similar (but sometimes slightly stronger) results about smooth 4-manifolds. They are technically much easier to work with than Donaldson invariants; for example, the moduli spaces of solutions of the Seiberg-Witten equations tend to be compact, so one avoids the hard problems involved in compactifying the moduli spaces in Donaldson theory.

For detailed descriptions of Seiberg-Witten invariants see (Donaldson 1996), (Moore 2001), (Morgan 1996), (Nicolaescu 2000), (Scorpan 2005, Chapter 10). For the relation to symplectic manifolds and Gromov-Witten invariants see (Taubes 2000). For the early history see (Jackson 1995).

Contents

[edit] SpinC-structures

The Seiberg-Witten equations depend on the choice of a SpinC-structure on a 4-manifold M. The group SpinC is

(U(1)×Spin(4))/(Z/2Z),

and there is a homomorphism from it to SO(4). A SpinC-structure on M is a lift of the natural SO(4) structure on the tangent bundle (given by the Riemannian metric and orientation) to the group SpinC. Every smooth compact 4-manifold M has SpinC-structures (though most do not have spin structures).

[edit] Seiberg-Witten equations

Fix a smooth compact 4-manifold M, choose a spinC-structure s on M, and write W+, W for the associated spinor bundles, and L for the determinant line bundle. Write φ for a self-dual spinor field (a section of W+) and A for a U(1) connection on L. The Seiberg-Witten equations for (φ,A)are

DAφ = 0
F^+_A=\sigma(\phi)

where DA is the Dirac operator of A, FA is the curvature 2-form of A, and FA+ is its self-dual part, and σ is the squaring map from W+ to imaginary self-dual 2-forms.

The solutions (φ,A) to the Seiberg-Witten equations are called monopoles.

[edit] The moduli space of solutions

The space of solutions is acted on by the gauge group, and the quotient by this action is called the moduli space of monopoles.

The moduli space is usually a manifold. A solution is called reducible if it is fixed by some non-trivial element of the gauge group. If b2+(M)≥1 then reducible solutions do not exist for generic metrics on M. The moduli space is a manifold except at reducible monopoles. So if b2+(M)≥1 then the moduli space is a (possibly empty) manifold for generic metrics. Moreover all components have dimension

(c1(s)2 − 2χ(M) − 3sign(M)) / 4.

The moduli space is empty for all but a finite number of spinC structures s, and is always compact.

A manifold M is said to be of simple type if the moduli space is finite for all s. The simple type conjecture states that if M is simply connected and b2+(M)≥2 then the moduli space is finite. It is true for symplectic manifolds. If b2+(M)=1 then there are examples of manifolds with moduli spaces of arbitrarily high dimension.

[edit] Seiberg-Witten invariants

The Seiberg-Witten invariants are easiest to define for manifolds M of simple type. In this case the invariant is the map from spinC structures s to Z taking s to the number of elements of the moduli space counted with signs.

If the manifold M has a metric of positive scalar curvature and b2+(M)≥2 then all Seiberg-Witten invariants of M vanish.

If the manifold M is the connected sum of two manifolds both of which have b2+≥1 then all Seiberg-Witten invariants of M vanish.

If the manifold M is simply connected and symplectic and b2+(M)≥2 then it has a spinC structure s on which the Seiberg-Witten invariant is 1. In particular it cannot be split as a connected sum of manifolds with b2+≥1.

[edit] References