Controlled Mather–Thurston theorems

IF 1.3 Q1 MATHEMATICS EMS Surveys in Mathematical Sciences Pub Date : 2023-10-24 DOI:10.4171/emss/63
Michael Freedman
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引用次数: 5

Abstract

Classical results of Milnor, Wood, Mather, and Thurston produce flat connections in surprising places. The Milnor–Wood inequality is for circle bundles over surfaces, whereas the Mather–Thurston theorem is about cobording general manifold bundles to ones admitting a flat connection. The surprise comes from the close encounter with obstructions from Chern–Weil theory and other smooth obstructions such as the Bott classes and the Godbillion–Vey invariant. Contradiction is avoided because the structure groups for the positive results are larger than required for the obstructions, e.g., $\operatorname{PSL}(2,\mathbb{R})$ versus $\operatorname{U}(1)$ in the former case and $C^1$ versus $C^2$ in the latter. This paper adds two types of control strengthening the positive results: In many cases we are able to (1) refine the Mather–Thurston cobordism to a semi-$s$-cobordism (ssc), and (2) provide detail about how, and to what extent, transition functions must wander from an initial, small, structure group into a larger one. The motivation is to lay mathematical foundations for a physical program. The philosophy is that living in the IR we cannot expect to know, for a given bundle, if it has curvature or is flat, because we cannot resolve the fine scale topology which may be present in the base, introduced by an ssc, nor minute symmetry violating distortions of the fiber. Small scale, UV, “distortions“ of the base topology and structure group allow flat connections to simulate curvature at larger scales. The goal is to find a duality under which curvature terms, such as Maxwell's $F \wedge F^\ast$ and Hilbert's $\int R, d\mathrm{vol}$ are replaced by an action which measures such “distortions“. In this view, curvature results from renormalizing a discrete, group theoretic, structure.
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受控Mather-Thurston定理
米尔诺、伍德、马瑟和瑟斯顿的经典结果在令人惊讶的地方产生了平连接。米尔诺-伍德不等式适用于曲面上的圆束,而马瑟-瑟斯顿定理是关于将一般流形束与允许平面连接的流形束结合在一起的。这个惊喜来自于与chen - weil理论中的障碍物和其他平滑障碍物(如Bott类和Godbillion-Vey不变量)的近距离接触。避免了矛盾,因为正结果的结构组比障碍所需的结构组大,例如,前一种情况下$\operatorname{PSL}(2,\mathbb{R})$与$\operatorname{U}(1)$,后一种情况下$C^1$与$C^2$。本文增加了两种类型的控制来加强积极的结果:在许多情况下,我们能够(1)将Mather-Thurston协同改进为半s -协同(ssc),并且(2)提供关于过渡函数如何以及在多大程度上必须从初始的小结构群漂移到更大的结构群的细节。其动机是为物理程序奠定数学基础。哲学是,生活在红外中,我们不能期望知道,对于一个给定的束,它是否有曲率或平坦,因为我们不能解决可能存在于基础中的精细尺度拓扑结构,由ssc引入,也不能解决纤维的微小对称性违反扭曲。小尺度,UV,基础拓扑和结构组的“扭曲”允许平面连接在更大尺度上模拟曲率。目标是找到一种对偶性,在这种对偶性下,曲率项,如麦克斯韦的$F \wedge F^\ast$和希尔伯特的$\int R, d\ mathm {vol}$被测量这种“扭曲”的作用所取代。在这个观点中,曲率是由一个离散的、群论的结构的重整而来的。
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2.30
自引率
0.00%
发文量
4
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