Yang-Mills energy quantization over non-collapsed degenerating Einstein manifolds and applications

Abstract

We investigate a sequence of Yang-Mills connections Aj lying in vector bundles Ej over non-collapsed degenerating closed Einstein 4-manifolds (Mj, g j) with uniformly bounded Einstein constants and bounded diameters. We establish a compactness theory modular three types of bubbles. As applications, we get some quantization results for several important topological number associated with the vector bundles, for instance, the first Pontrjagin numbers p1(E) of vector bundles over Einstein 4-manifolds and the Euler numbers (M;E) of holomorphic vector bundles over K\"ahler-Einstein surfaces. Furthermore, we get some quantization results about the volume v(Lj) and certain cohomological numbers (e.g. dim H0(Mj;Lj)) of holomorphic line bundles Lj over non-collapsed degenerating K\"ahler-Einstein surfaces (Mj,Jj,gj) with the aid of the classical vanishing theorems, the classical Hirzebruch-Riemann-Roch type theorems, and the profound convergence theory of K\"ahler-Einstein manifolds. In particular, we obtain some interesting identities involving non-collapsed degenerating compact K\"ahler-Einstein surfaces with non-zero scalar curvature, which indicate that we can know the Euler number of Mj for large j provided some topological information of the limit orbifold M∞. For K\"ahler-Einstein Del Pezzo surfaces, an interesting implication is that we can provide some preliminary estimates for the number of singularities of various types in M∞ in an effective way. As an unexpected surprise, we find an identity which connects Milnor numbers for singularities in M∞ and the correction terms in the Hirzebruch-Riemann-Roch theorem for orbifolds. Some quantization results can be extended to the case of higher dimensional n-manifolds.

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