Hessian geometry and Frobenius manifolds with curvature

TL;DR

This paper explores the relationship between Hessian metrics and curved Frobenius manifolds, showing that certain curved structures naturally derive from Hessian metrics and linking them to superintegrable systems.

Contribution

It demonstrates that curved Frobenius manifolds on constant curvature spaces can be compatible with Hessian structures through a finite type prolongation system, unifying these geometric concepts.

Findings

Curved Frobenius structures are natural examples arising from Hessian metrics.

Compatibility with Hessian structures requires a closed prolongation system of finite type.

Certain superintegrable systems correspond uniquely to compatible Frobenius-Hessian structures.

Abstract

A Riemannian metric is called Hessian if, locally, it can be written as the Hessian of a function called the Hessian potential. A (flat) Manin-Frobenius manifold is a flat Riemannian manifold furnished with a commutative and associative product compatible with the metric, such that a certain potentiality property is satisfied. Curved Frobenius manifolds generalize this concept to spaces with non-vanishing curvature, and they have applications in supersymmetric mechanics and within the theory of submanifolds. Curved Frobenius manifolds naturally arise from Hessian metrics, and we find that they, conceptually, are the typical non-trivial examples. We obtain that Curved Frobenius structures on constant curvature spaces are consistent with a Hessian structure, if they satisfy a closed prolongation system of finite type. Consistency means that the Frobenius potential and the Hessian potential can be identified. As an application, we show that certain second-order maximally superintegrable systems correspond 1-to-1 to Curved Frobenius structures that are consistent with a Hessian structure.