We commenced the project by finding a unified framework for deducing numerous functional inequalities on a weighted Riemannian manifold and its boundary satisfying the Curvature Dimension (CD) condition. These inequalities are known to be intimately connected to the Brunn--Minkowski inequality, a fundamental inequality in Convexity Theory which lies at the heart of our project. Armed with these new tools in the Riemannian setting, we obtained new concentration results in the purely Euclidean setting. Our idea was to change the Euclidean metric to a more general Riemannian one, and perform our analysis on the resulting weighted Riemannian manifold.
We continued to address a strengthened conjectured version of the classical Brunn-Minkowski inequality for origin-symmetric convex bodies. We confirmed that such a (local) strengthening does exist, but with non-optimal magnitude. It turns out that this problem is equivalent to a spectral minimization problem of a certain second-order differential operator introduced by Hilbert on appropriate weighted Riemannian manifold. In addition, we were able to improve the best-known stability estimates for the Brunn--Minkowski and anisotropic isoperimetric inequalities, two important objects of study in our project.
We resolved the isoperimetric conjecture of Kannan, Lovász and Simonovits, a central question in our project, on the subclass of generalized Orlicz balls, thereby significantly enlarging the class of convex bodies for which the conjecture has been confirmed.
It turned out that the tools we developed enabled us to go beyond the Riemannian setting, and we were able to establish sharp Poincaré inequalities on metric-measure (mm) spaces satisfying the MCP condition. We subsequently extended these results to all L^p-Poincaré and log-Sobolev estimates for even more general mm-spaces satisfying the Quasi Curvature Dimension condition, which we introduced, yielding almost optimal results on the Heisenberg group and other sub-Riemannian manifolds.
In the second half of our project, our Riemannian vantage-point enabled us to resolve several long-standing open problems:
- a conjecture of Sturm and Villani regarding whether their CD condition on very general mm-spaces enjoys the local-to-global property.
- the Gaussian double-bubble and more generally multi-bubble isoperimetric conjectures - see the attached figure for the optimal partition of Gauss space on R^2 into three parts and on R^3 into four parts.
- a conjecture of Lutwak on the isoperimetric minimizers of the affinely-invariant quermassintegrals in the higher-rank case.
Towards the end of the project, we continued to study the affine-invariant setting, revealing a novel connection between the Brunn-Minkowski theory and affine differential geometry. We were thus able to resolve the isomorphic version of the log-Brunn-Minkowski conjecture, as well as resolving the conjecture in full for convex bodies with appropriately pinched curvature.
Dissemination:
I have given 32 talks at different venues in Europe, USA and Israel, to an overall estimated audience of well over 1000 people.
I have written 16 project-related papers which are all open-access and available to the public.
I have had 4 post-docs and 1 PhD Student, and we have been conducting periodic meetings and discussions regarding various project-related Mathematics; these young researchers have written an additional 11 project-related papers and 1 Ph.D. Thesis. All of my post-docs are nowadays Assistant Professors in departments around the world.