On orthogonal Ricci curvature

Advances in Complex Geometry Pub Date : 1900-01-01 DOI:10.1090/conm/735/14827

Lei Ni, F. Zheng

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引用次数: 15

Abstract

In this paper we discuss some recent progresses in the study of compact Kähler manifolds with positive orthogonal Ricci curvature, a curvature condition defined as the difference between Ricci curvature and holomorphic sectional curvature. In the recent works by authors and the joint work of authors with Q. Wang the comparison theorems, vanishing theorems, and structural theorems for such manifolds have been proved. We also constructed examples of this type of manifolds, and give some classification results in low dimensions. 1. Orthogonal Ricci curvature Let (M, g) be a Kähler manifold of complex dimension n. Its orthogonal Ricci curvature Ric⊥ is defined by (cf. [21]): Ric⊥ XX = Ric(X,X)−R(X,X,X,X)/|X|, where X is a non-zero type (1, 0) tangent vector at a point x ∈ M. This curvature arises in the study of the comparison theorem for Kähler manifolds and the previous study of manifolds with so-called nonnegative quadratic orthogonal bisectional curvature (cf. [4], [26], [16], [5]). We refer the readers to [21] for a more detailed account on this topic. Clearly this curvature is closely related to Ricci curvature Ric and holomorphic sectional curvature H. It is natural to ask, what is the relationship between Ric⊥ and Ric or H (other than the obvious one that Ric⊥ + H = Ric for unit length tangent vectors), and what kind of compact complex manifolds M can admit Kähler metrics with Ric⊥ > 0 (or ≥ 0, or ≤ 0, or < 0, or ≡ 0) everywhere? In this paper, we will focus on the curvature condition Ric⊥ and pay particular attention to the class of compact Kähler manifolds with Ric⊥ > 0 everywhere, except in Section 2 where complete noncompact Kähler manifolds are also considered. Throughout this paper, we will assume that the complex dimension n ≥ 2 unless stated otherwise, since Ric⊥ ≡ 0 when n = 1. We start with the following observation. At a point x ∈ M, let us denote by S2n−1 x the unit sphere of all type (1, 0) tangent vector at x of unit length. By a classic result of Berger, The research of LN is partially supported by NSF grant DMS-1401500 and the “Capacity Building for Sci-Tech Innovation-Fundamental Research Funds”. The research of FZ is partially supported by a Simons Collaboration Grant 355557.

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在正交里奇曲率上

本文讨论了具有正正交Ricci曲率的紧致Kähler流形的一些最新研究进展，正正交Ricci曲率是定义为Ricci曲率与全纯截面曲率之差的曲率条件。在作者最近的工作和与王q .的合作工作中，证明了这种流形的比较定理、消失定理和结构定理。我们还构造了这类流形的例子，并给出了一些低维的分类结果。1. 设(M, g)是复维数n的Kähler流形。它的正交里奇曲率Ric⊥由(cf.[21])定义:Ric⊥XX = Ric(X,X)−R(X,X,X,X)/|X|，其中X是点X∈M处的非零型(1,0)切向量。这个曲率出现在Kähler流形的比较定理研究中，以及之前对具有所谓非负二次正交对分曲率的流形的研究中(cf.[4]，[26]，[16]，[5])。我们请读者参阅[21]以获得关于该主题的更详细的说明。显然，这个曲率与Ricci曲率Ric和全纯截面曲率H密切相关，很自然地要问，Ric⊥与Ric或H之间的关系是什么(除了对于单位长度切向量的明显的Ric⊥+ H = Ric)，以及什么样的紧复流形M可以允许Kähler处处存在Ric⊥> 0(或≥0，或≤0，或< 0，或≡0)的度量?在本文中，我们将专注于曲率条件Ric⊥，并特别关注Ric⊥> 0的紧态Kähler流形的类别，除了在第2节中也考虑了完全非紧态Kähler流形。在本文中，除非另有说明，否则我们将假设复维数n≥2，因为当n = 1时，Ric⊥≡0。我们从以下观察开始。在点x∈M处，用S2n−1x表示x处单位长度的所有类型(1,0)切向量的单位球。根据Berger的经典结果，LN的研究得到了美国国家科学基金DMS-1401500和“科技创新能力建设-基础研究基金”的部分支持。FZ的研究得到了Simons合作基金355557的部分支持。

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Advances in Complex Geometry

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