Geometry of Clairaut Riemannian warped product submersions

TL;DR

This paper introduces and analyzes Clairaut Riemannian warped product submersions, establishing conditions for their structure, examining curvature properties, and providing explicit formulas and examples to understand their geometric behavior.

Contribution

It generalizes Clairaut Riemannian submersions to warped products, deriving conditions, curvature formulas, and exploring geometric and Einstein properties.

Findings

Clairaut condition holds when the girth function has a horizontal gradient.

Explicit curvature formulas relate warping functions to geometric properties.

Conditions for trivial warping, local symmetry, and Einstein metrics are established.

Abstract

In this paper, we introduce and study the concept of \textit{Clairaut Riemannian warped product submersions} between Riemannian warped product manifolds. By generalizing the notion of Clairaut Riemannian submersions to the setting of Riemannian warped product submersions, we define such submersions via a warping function satisfying a Clairaut relation along geodesics. We establish necessary and sufficient conditions under which a Riemannian warped product submersion satisfies the Clairaut condition, showing that it holds if and only if the girth function defining the Clairaut condition has a horizontal gradient, one component of the fibers is totally geodesic, and the other is totally umbilical with mean curvature vector governed by the warping function. We examine the geometric consequences of this structure, study the harmonicity conditions, and the behavior of the Weyl tensor, etc. Additionally, we illustrate the theory with several non-trivial examples. In the latter part of the paper, we explore a detailed study of the curvature behavior of such submersions. Explicit formulas for the Riemannian, Ricci, and sectional curvature tensors of the source space are derived in terms of the geometry of the target and fiber manifolds, as well as the warping and girth functions. These computations provide geometric insight into how warping and the Clairaut condition affect curvature properties, such as conformal flatness and the non-positivity of certain mixed curvatures. We also analyze the conditions for a trivial warping of the source manifold and for the fibers to be locally symmetric. Furthermore, the Einstein condition has been explored in various scenarios. Finally, we also extend and answer a question posed in [2] to the setting of Clairaut warped product submersion.