## One Day Workshop on Metric Geometry

**Time：**December 16, 2017

**Venue：** Room 77201, Jingchunyuan 78, BICMR

**Organizer: **

Jian Ge (BICMR)

**Speaker:**

Xiaoyang Chen (Tongji University)

Yushen Wang (Beijing Normal University)

Guoyi, Xu (YMSC, Tsinghua University)

Shicheng Xu (Capital Normal University)

Masoumeh Zarei (BICMR, Peking University)

**Schedule:**

9:00-10:00 Xiaoyang Chen

10:00-10:30 Tea Break

10:30-11:30 Masoumeh Zarei

Lunch Break

1:30-2:30 Yushen Wang

2:30-3:00 Guoyi Xu

3:00-3:30 Tea Break

3:30-4:30 Shicheng Xu

**Abstract:**

Xiaoyang Chen,

Title: Symplectic aspects of polar actions

Abstract: Polar actions are a special class of isometric group actions on Riemannian manifolds. We will give a symplectic look at polar actions and discuss its application in symplectic geometry. This is a joint work with Jianyu Ou.

Yusheng Wang

Title: Radial cone-neighborhood isometry in Alexandrov geometry

Abstract: We will introduce a new definition in Alexandrov geometry with lower curvature bound: Radial cone-neighborhood isometry. And we will show its applications, e.g., to prove Soul Conjecture in Alexandrov geometry in dimension 4. This is based on joint works with Professor Xiaochun Rong.

Guoyi Xu

Title: The integral of the curvature

Abstract: The classical Gauss-Bonnet theorem in 19th century links the integral of the curvature to the topology of compact manifolds in 2-dim case. The well-known Gauss-Bonnet-Chern theorem generalize this result to higher dimension in 1940’s.On the other hand, Cohn-Vossen’s inequality opened the door of estimating the integral of the curvature on non-compact manifolds in 2-dim in 1930’s. However, the higher dimension version of Cohn-Vossen’s inequality is still missing, although Yau posed one open question along this line in 1990’s. We will survey the history of the study around the integral of the curvature, from Gauss, Bonnet, Chern, Yau to the current state, my recent research result will also be presented. The key idea of the proof will be presented in the talk, some elementary topology and Riemannian geometry knowledge is enough to understand most of the talk.

Shicheng Xu

Title: First eigenvalue pinching and quantitative rigidity of geodesic spheres in a Riemannian manifold.

Abstract: Let us imagine that there is an immersed hypersurface M in a complete manifold N. If one knocks M to hear the first eigenvalue of M and compare it to the average/maximum mean curvature of M, is there any chance that the shape of M and the ambient geometry of N around M can be determined by those information? We prove that in certain cases it is true. To be precisely, let M be immersed to a convex ball of radius less than \pi/4√K, where K is the upper sectional curvature bound of N (4√K=\infty if K<=0), then it was well-known by Heintze (1988) that λ1 <=n(K+|H|), where |H| is either the average or the maximum of the mean curvature of M (depending on the sign of K). We prove that if λ1>=n(K+|H|)(1-ε), where ε depends on the dimension and the lower curvature bound of N, then M is embedded, Hausdorff close and diffeomorphic to a geodesic sphere in N, and the domain Ω enclosed by M is Gromov-Hausdorff close to a convex ball of constant sectional curvature K. If λ1=n(K+|H|), then M and Ω are a geodesic sphere and a convex ball of constant curvature K respectively. The proof involves the method of Moser iteration, comparison geometry and some fundamental facts in Cheeger-Colding's theory. It is a recent joint work with Yingxiang Hu.