Characterizing families of graph manifolds via suitable classes of simple fold maps into the plane and embeddability of the Reeb spaces in some 3-dimensional manifolds

TL;DR

This paper explores how simple fold maps into the plane can characterize graph manifolds and investigates the embeddability of associated polyhedra, linking singularity theory with topological invariants of 3-manifolds.

Contribution

It introduces new characterizations of graph manifolds using simple fold maps and examines the embeddability of related polyhedra in 3-manifolds.

Findings

Graph manifolds are characterized by simple fold maps into the plane.

Induced quotient maps produce simple polyhedra related to manifold shadows.

Embeddability of these polyhedra provides invariants for graph manifolds.

Abstract

Graph manifolds form important classes of $3$-dimensional closed and orientable manifolds. For example, {\it Seifert} manifolds are graph manifolds where hyperbolic manifolds are not. In applying singularity theory of differentiable maps to understanding global topologies of manifolds, graph manifolds have been shown to be characterized as ones admitting so-called simple fold maps into the plane of explicit classes by Saeki and the author. The present paper presents several related new results. Fold maps are higher dimensional variants of Morse functions and simple ones form simple classes, generalizing the class of general Morse functions. Such maps into the plane on $3$-dimensional closed and orientable manifolds induce quotient maps to so-called simple polyhedra with no vertices, which are $2$-dimensional. This is also closely related to the theory of {\it shadows} of $3$-dimensional manifolds. We also discuss invariants for graph manifolds via embeddability of these polyhedra in some $3$-dimensional manifolds.