Wasserstein geometry and Ricci curvature bounds for Poisson spaces
Lorenzo Dello Schiavo, Ronan Herry, Kohei Suzuki

TL;DR
This paper explores the geometric structure of Poisson spaces using optimal transport and Ricci curvature bounds, establishing a Riemannian framework, a Wasserstein-like distance, and key geometric inequalities.
Contribution
It introduces a formal Riemannian structure and a Wasserstein-type distance on Poisson space measures, extending geometric analysis tools to this infinite-dimensional setting.
Findings
Poisson space has Ricci curvature bounded below by 1 in the entropic sense.
The Ornstein-Uhlenbeck semi-group is the gradient flow of the relative entropy.
The extended distance satisfies an HWI inequality.
Abstract
Let be the configuration space over a complete and separable metric base space, endowed with the Poisson measure . We study the geometry of from the point of view of optimal transport and Ricci-lower bounds. To do so, we define a formal Riemannian structure on , the space of probability measures over with finite first moment, and we construct an extended distance on . The distance corresponds, in our setting, to the Benamou--Brenier variational formulation of the Wasserstein distance. Our main technical tool is a non-local continuity equation defined via the difference operator on the Poisson space. We show that the closure of the domain of the relative entropy is a complete geodesic space, when endowed with . We establish non-local…
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Taxonomy
TopicsGeometric Analysis and Curvature Flows · Heme Oxygenase-1 and Carbon Monoxide · Ophthalmology and Eye Disorders
