Flows, growth rates, and the veering polynomial

TL;DR

This paper links veering triangulations, flow graphs, and a modified veering polynomial to analyze growth rates of closed orbits in pseudo-Anosov flows on 3-manifolds, extending McMullen's work and exploring entropy and stretch factors.

Contribution

It introduces a method to realize veering triangulations with transversality properties and uses a modified polynomial to compute orbit growth rates, generalizing existing fibered setting results.

Findings

Veering triangulation can be realized with 2-skeleton positively transverse to the flow.

Flow graph encodes orbits and helps compute growth rates.

Results apply even when the transverse surface is on the boundary of a fibered cone.

Abstract

For certain pseudo-Anosov flows $\phi$ on closed $3$-manifolds, unpublished work of Agol--Gu\'eritaud produces a veering triangulation $\tau$ on the manifold $M$ obtained by deleting $\phi$'s singular orbits. We show that $\tau$ can be realized in $M$ so that its 2-skeleton is positively transverse to $\phi$, and that the combinatorially defined flow graph $\Phi$ embedded in $M$ uniformly codes $\phi$'s orbits in a precise sense. Together with these facts we use a modified version of the veering polynomial, previously introduced by the authors, to compute the growth rates of $\phi$'s closed orbits after cutting $M$ along certain transverse surfaces, thereby generalizing work of McMullen in the fibered setting. These results are new even in the case where the transverse surface represents a class in the boundary of a fibered cone of $M$. Our work can be used to study the flow $\phi$ on the original closed manifold. Applications include counting growth rates of closed orbits after cutting along closed transverse surfaces, defining a continuous, convex entropy function on the `positive' cone in $H^1$ of the cut-open manifold, and answering a question of Leininger about the closure of the set of all stretch factors arising as monodromies within a single fibered cone of a $3$-manifold. This last application connects to the study of endperiodic automorphisms of infinite-type surfaces and the growth rates of their periodic points.