On the Rosenberg-Stolz Conjecture for X × R2 and Its Application in Complex Geometry
Abstract
Let X be an oriented, closed manifold with X ≥slant 2 . In this article, we give both Riemannian geoemtry and complex geometry results on (sub)manifolds of the type X × Ck or X × Rk . For Riemannian geometry side, we show that if X × C = X × R2 admits a Riemannian metric g with uniformly positive scalar curvature and bounded curvature, such that some novel conformally invariant g -angle condition is satisfied, then there exists a complete metric g conformal to g such that g |X has positive scalar curvature. This Riemannian path implies a complex geometry result: we show that if the complex manifold X × C admits a Hermitian metric ω whose associated Riemannian metric g has uniformly positive scalar curvature and is of bounded curvature, then X × C admits a Hermitian metric ω with positive Chern scalar curvature, provided that some g -angle condition is satisfied. The Riemannian geometry result partially answers a 1994 Rosenberg-Stolz conjecture in all dimensions. The complex geometry result extends a result of XiaoKui Yang from compact Hermitian manifolds to noncompact Hermitian manifolds of type X × C . We further generalize both the Riemannian and complex geometry results to X × Rk or X × Ck for any k ≥slant 1 by imposing a generalized conformally invariant angle condition.
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