时间：2026年4月10日-4月12日

地点：西湖大学云谷校区E14-116

Tencent Meeting: 842-6964-3875

PASSCODE: 0410

4月10日

9:00-10:10

Speaker: 王虹 IHES、柯朗数学研究所（线上）

Title：TBD

Abstract：TBD

10:40-11:50

Speaker: 耿俊 兰州大学

Title：Neumann Problems for the Stokes Equations in Convex Domains

Abstract：This paper studies the Neumann boundary value problems for the Stokes equations in a convex domain in $\mathbb{R}^d$. We obtain nontangential-maximal-function estimates in $L^p$ and $W^{1, p}$ estimates for $p$ in certain ranges depending on $d$. This is a joint work with Professor Zhongwei Shen.

4月11日

9:00-10:10

Speaker: 郏浩 明尼苏达大学（线上）

Title: Sharp asymptotic stability of Kolmogorov flows on a non-square torus

Abstract: The Kolmogorov flow is an important metastable state for the two dimensional Navier Stokes equations on a (non-square) torus when the viscosity is $\nu\ll1$. It was first proposed by Kolmogorov in 1959 as a model to study transition to turbulence. Yudovich proved global stability of the Kolmogorov flow and showed that perturbed solutions converge back to the Kolmogorov flow with the exponential rate $e^{-\nu t}$ as $t\to\infty$. However, numerical simulations have revealed that a large family of solutions relax at a much faster rate. For a long time, the precise mechanisms for such rapid convergence were not understood, despite much effort. In this talk, we present a recent result showing that when the perturbation is of size $\ll \nu^{1/3}$ in $H^3$, the perturbed solution converges to a shear flow with a fast, optimal rate $\frac{1}{1+\nu t^3} e^{-c_0\nu^{1/2}t}$, before settling down to the Kolmogorov flow and slowly decaying to 0. The threshold $\nu^{1/3}$ is expected to be sharp, and is quite surprising since it is the same as that for the much simpler Couette flow where linear decay is significantly stronger. The proof relies essentially on sharp estimates on all three known stabilizing mechanisms for incompressible fluid equations: inviscid damping, enhanced dissipation and vorticity depletion. Based on joint work with Qi Chen, Dongyi Wei and Zhifei Zhang.

10:40-11:50

Speaker: 庞逸轩 宾夕法尼亚大学（线上）

Title：Weighted mixed-norm estimates for circular averages and exceptional set estimates for the wave equation

Abstract：We prove new weighted mixed-norm estimates for circular averages, using circle tangency bounds and a discretized slicing lemma for fractals. These estimates can be seen as X-ray-type extensions of Wolff's and Bourgain's circular maximal functions. As applications, we obtain new exceptional set estimates for the radial integrability of functions in Lebesgue spaces, as well as for the Hölder regularity in time of solutions to the linear wave equation on R^2. The latter results are the first of their kind. This is joint work with Chenjian Wang.

14:00-15:10

Speaker: 王兴 湖南大学

Title: Problems related to eigenfunctions on compact manifolds

Abstract: In this report, I will share my perspective on eigenfunctions on compact manifolds based on my recent work, along with some open problems related to my research.

15:30-16:40

Speaker: 张军勇 北京理工大学

Title：Geodesic flow focusing and dispersive estimates

Abstract：In this talk, we will present recent results on pointwise dispersive estimates for Schrödinger operators on manifolds with conical singularities. We will discuss how the geometry of the geodesic flow, particularly the phenomenon of focusing, influences the long-time decay of solutions. This work is based on a series of joint papers with Q. Jia (Australian National University).

16:50-18:00

Speaker: 甘盛文 中山大学

Title: Some new estimates for Falconer's distance set problem

Abstract: Given a set E in R^2, the distance set of E is defined as \Delta(E)={ |x-y|: x,y \in E }. It is conjectured that if the Hausdorff dimension of E exceeds 1, then \Delta(E) has positive Lebesgue measure. In this talk, I will first discuss the history of this problem and survey some classical approaches. I will then introduce some new ideas that help to improve the previous results. This is a joint work with Bochen Liu and Shukun Wu.

4月12日

9:00-10:10

Speaker: 吴澍坤 印第安纳大学（线上）

Title: Two-ends incidence estimates with applications

Abstract: For a small parameter \delta, let L be a \delta-separated family of truncated lines in [0,1]^n. For each such line, let the shading Y(l) be a union of \delta-balls contained in the \delta-neighborhood of l. Finding lower bounds for the volume of the union of these shadings under various assumptions has appeared to be inevitable in modern Fourier analysis since Bourgain's foundational work in 1991. In this talk, we study the case where the shadings Y(l) satisfy a weak non-concentration assumption, namely the two-ends condition, and discuss some of its applications. We also give a streamlined proof sketch of the two-ends Furstenberg estimate in the plane, using the Furstenberg set estimate as the only black box. We hope this offers a clean illustration of the recent "small multiplicity--large volume" methodology.

10:40-11:50

Speaker: 刘博辰 南方科技大学

Title: Lebesgue measure of distance sets with regular pins and multi-scale Mizohata-Takeuchi-type estimates

Abstract: I prove that, if a regular planar set has dimension greater than 1, then its distance set must have positive Lebesgue measure. This settles the regular case of the Falconer distance conjecture in the plane.

14:00-15:10

Speaker: 席亚昆 浙江大学

Title：Restriction conjecture, Bochner-Riesz conjecture and a question of Hörmander

Abstract：This talk presents progress on the restriction problem, Bochner–Riesz summability. In particular, we provide a full solution to a question of Hörmander.

15:30-16:40

Speaker: 何伟鲲 中国科学院数学与系统科学研究院

Title：Quantitative Brascamp-Lieb inqualities

Abstract：I will present a new estimate on the constant in Brascamp-Lieb inequalities. This can be regarded as a generalisation of the finiteness criterion of Bennett-Carbery-Christ-Tao. This work is motivated by its applications to projection theory and to dynamical systems. Based on joint work with Timothée Bénard.

16:50-18:00

Speaker: 郭少明 南开大学

Title：一般流形上的Kakeya 问题

Abstract：报告的内容是关于一般流形（黎曼流形或者更一般的路径几何）上的Kakeya 问题。 首先我们会看到每一个Kakeya问题都会诱导出一个路径几何； 有了这个路径几何， 我们就可以用这个几何上的曲率（Weyl曲率和Douglas曲率）来刻画我们的Kakeya问题。

来源：https://its.westlake.edu.cn/info/1125/3549.htm