The Painlev\'e III equation of type (0,0,4,-4), its associated vector bundles with isomonodromic connections, and the geometry of the movable poles

TL;DR

This paper explores the geometric structures underlying a specific Painlevé III equation, linking it to isomonodromic vector bundles, and provides new insights into the global behavior of its real solutions and their poles.

Contribution

It introduces a conceptual framework for the geometric objects of Painlevé equations and presents new results on the global structure and asymptotics of solutions for P_{III}(0,0,4,-4).

Findings

Global description of zeros and poles of real solutions

Asymptotic behavior near zero and infinity

Connection between Painlevé III and geometric vector bundles

Abstract

The paper is about a Painlev\'e III equation and its relation to isomonodromic families of vector bundles on P^1 with meromorphic connections. The purpose of the paper is two-fold: it offers a conceptual language for the geometrical objects underlying Painlev\'e equations, and it offers new results on a particular Painlev\'e III equation, which we denote by P_{III}(0,0,4,-4). This is equivalent to the radial sine (or sinh) Gordon equation and, as such, it appears very widely in geometry and physics. Complex multi-valued solutions on C^* are the natural context for most of the paper, but in the last three chapters real solutions on the positive real line (with or without singularities) are addressed. Results about the asymptotics of real solutions near 0 and near infinity are combined with results on the global geometry of the moduli spaces of initial data and monodromy data. This leads to a new global picture of all zeros and poles of all real solutions on the positive real line.