Complete classification of rational solutions of $A_{2n}$-Painlev\'{e} systems

TL;DR

This paper classifies all rational solutions of the $A_{2n}$-Painlevé systems, showing they can be explicitly constructed using Hermite polynomials, Maya diagrams, and Bäcklund transformations, thus providing a complete understanding of these solutions.

Contribution

It offers a complete classification and explicit representation of rational solutions to the $A_{2n}$-Painlevé systems using Maya diagrams, Hermite polynomials, and symmetry group actions.

Findings

Rational solutions correspond to cycles of Maya diagrams.

All rational solutions can be expressed as Wronskian determinants of Hermite polynomials.

The classification links solutions to trivial monodromy potentials and symmetry transformations.

Abstract

We provide a complete classification and an explicit representation of rational solutions to the fourth Painlev\'e equation PIV and its higher order generalizations known as the $A_{2n}$-Painlev\'e or Noumi-Yamada systems. The construction of solutions makes use of the theory of cyclic dressing chains of Schr\"odinger operators. Studying the local expansions of the solutions around their singularities we find that some coefficients in their Laurent expansion must vanish, which express precisely the conditions of trivial monodromy of the associated potentials. The characterization of trivial monodromy potentials with quadratic growth implies that all rational solutions can be expressed as Wronskian determinants of suitably chosen sequences of Hermite polynomials. The main classification result states that every rational solution to the $A_{2n}$-Painlev\'e system corresponds to a cycle of Maya diagrams, which can be indexed by an oddly coloured integer sequence. Finally, we establish the link with the standard approach to building rational solutions, based on applying B\"acklund transformations on seed solutions, by providing a representation for the symmetry group action on coloured sequences and Maya cycles.