阿贝尔三重的Donaldson–Thomas不变量和Bridgeland稳定性条件

IF 0.9 1区数学 Q2 MATHEMATICS

Journal of Algebraic Geometry Pub Date : 2018-08-08 DOI:10.1090/JAG/788

G. Oberdieck, D. Piyaratne, Yukinobu Toda

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引用次数: 7

摘要

我们利用Bridgeland稳定性条件研究了阿贝尔三重的约化Donaldson–Thomas理论。主要结果是在所有导出的自等价下，直到明确给定的壁交叉项，约化Donaldson–Thomas不变量的不变性。我们还根据判别函数提出了一个不存在墙的数值标准。对于Picard秩为1的主极化阿贝尔三重，详细讨论了其穿墙贡献。讨论为Bryan、Pandharipande、Yin和第一作者提出的曲线计数不变量的推测公式提供了证据。对于证明，我们加强了关于阿贝尔三重的Bridgeland稳定性条件的几个已知结果。我们证明了先前构造的某些稳定性条件满足完全支撑性质。特别地，稳定性歧管是非空的。我们还证明了Gieseker室的存在，并确定了所有的穿墙贡献。给出了具有阿贝尔作用的任意Calabi–Yau三重的约化广义Donaldson–Thomas不变量的定义。

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Donaldson–Thomas invariants of abelian threefolds and Bridgeland stability conditions

We study the reduced Donaldson–Thomas theory of abelian threefolds using Bridgeland stability conditions. The main result is the invariance of the reduced Donaldson–Thomas invariants under all derived autoequivalences, up to explicitly given wall-crossing terms. We also present a numerical criterion for the absence of walls in terms of a discriminant function. For principally polarized abelian threefolds of Picard rank one, the wall-crossing contributions are discussed in detail. The discussion yields evidence for a conjectural formula for curve counting invariants by Bryan, Pandharipande, Yin, and the first author. For the proof we strengthen several known results on Bridgeland stability conditions of abelian threefolds. We show that certain previously constructed stability conditions satisfy the full support property. In particular, the stability manifold is non-empty. We also prove the existence of a Gieseker chamber and determine all wall-crossing contributions. A definition of reduced generalized Donaldson–Thomas invariants for arbitrary Calabi–Yau threefolds with abelian actions is given.

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来源期刊

Journal of Algebraic Geometry 数学-数学

CiteScore

2.70

自引率

5.60%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Algebraic Geometry is devoted to research articles in algebraic geometry, singularity theory, and related subjects such as number theory, commutative algebra, projective geometry, complex geometry, and geometric topology. This journal, published quarterly with articles electronically published individually before appearing in an issue, is distributed by the American Mathematical Society (AMS). In order to take advantage of some features offered for this journal, users will occasionally be linked to pages on the AMS website.