Gravitational instantons are interesting, as they offer insights into the quantization of gravity. For example, positive definite asymptotically locally Euclidean metrics are needed as they obey the positive-action conjecture; actions that are unbounded below create divergence in the quantum path integral.
By specifying the 'boundary conditions', i.e. the asymptotics of the metric 'at infinity' on a noncompact Riemannian manifold, gravitational instantons are divided into a few classes, such as asymptotically locally Euclidean spaces, asymptotically locally flat spaces. They can be further characterized by whether the Riemann tensor is self-dual, whether the Weyl tensor is self-dual, or neither; whether or not they are Kahler manifolds; and various characteristic classes, such as Euler characteristic, the Hirzebruch signature, the Rarita—Schwinger index, or generally the Chern class. The ability to support a spin structure is another appealing feature.
Page space, a rotating compact metric on the direct sum of two complex projective planes.
The Gibbons-Hawking multi-center metrics, given below.
The Taub-bolt metric and the rotating Taub-bolt metric. The "bolt" metrics have a cylindrical-type coordinate singularity at the origin, as compared to the "nut" metrics, which have a sphere coordinate singularity. In both cases, the coordinate singularity can be removed by switching to Euclidean coordinates at the origin.
The K3 surfaces.
The asymptotically locally Euclidean self-dual manifolds, including the lens spaces, the double-coverings of the dihedral groups, the tetrahedral group, the octahedral group, and the icosahedral group. Note that corresponds to the Eguchi-Hanson instanton, while for higher k, the corresponds to the Gibbons-Hawking multi-center metrics.
This is an incomplete list; there are others.
Examples
It will be convenient to write the gravitational instanton solutions below using left-invariant 1-forms on the three-sphereS3 or SU). These can be defined in terms of Euler angles by Note that for cyclic.
Taub–NUT metric
Eguchi–Hanson metric
The Eguchi–Hanson space is defined by a metric the cotangent bundle of the 2-sphere. This metric is where. This metric is smooth everywhere if it has no conical singularity at,. For this happens if has a period of, which gives a flat metric on R4; However, for this happens if has a period of. Asymptotically the metric looks like which naively seems as the flat metric on R4. However, for, has only half the usual periodicity, as we have seen. Thus the metric is asymptotically R4 with the identification, which is a Z2subgroup of SO, the rotation group of R4. Therefore, the metric is said to be asymptotically R4/Z2. There is a transformation to another coordinate system, in which the metric looks like where In the new coordinates, has the usual periodicity One may replace V by For some n points, i = 1, 2..., n. This gives a multi-center Eguchi-Hanson gravitational instanton, which is again smooth everywhere if the angular coordinates have the usual periodicities. The asymptotic limit is equivalent to taking all to zero, and by changing coordinates back to r, and, and redefining, we get the asymptotic metric This is R4/Zn = C2/Zn, because it is R4 with the angular coordinate replaced by, which has the wrong periodicity. In other words, it is R4 identified under, or, equivalently, C2 identified under zi ~ zi for i = 1, 2. To conclude, the multi-center Eguchi-Hanson geometry is a KählerRicci flat geometry which is asymptotically C2/Zn. According to Yau's theorem this is the only geometry satisfying these properties. Therefore, this is also the geometry of a C2/Znorbifold in string theory after its conical singularity has been smoothed away by its "blow up".
Gibbons–Hawking multi-centre metrics
The Gibbons-Hawking multi-center metrics are given by where Here, corresponds to multi-Taub-NUT, and is flat space, and and is the Eguchi-Hanson solution.
