Wrinkling and Haefliger structures

TL;DR

This paper explores the relationship between wrinkling techniques and Haefliger structures, showing how wrinkling can be viewed as a holonomic approximation and establishing connectivity results in the context of partial differential relations.

Contribution

It extends the concept of wrinkled submersions to a broader setting and demonstrates how Haefliger structures facilitate general wrinkling statements and their homotopy properties.

Findings

Wrinkling can be interpreted as holonomic approximation.

Haefliger structures provide a framework for general wrinkling.

Connectivity results relate solutions of $\\mathcal{R}$ to their formal counterparts.

Abstract

Wrinkling techniques, introduced by Eliashberg and Mishachev, are typically used to prove h-principles of the form: ``formal solutions of a partial differential relation $\mathcal{R}$ can be deformed to singular/wrinkled solutions''. What a wrinkled solution is depends on the context, but the overall idea is that it should be an object that fails to be a solution only due to the presence of mild/controlled singularities. Much earlier, Haefliger structures were introduced by Haefliger as singular analogues of foliations. Much like a foliation is locally modeled on a submersion, a Haefliger structure is modeled on an arbitrary map. This implies that Haefliger structures have better formal properties than foliations. For instance, they can be pulled back by arbitrary maps and admit a classifying space. In [12], the second and third authors generalized the \emph{wrinkled embeddings} of Eliashberg and Mishachev to arbitrary order. This paper can be regarded as a sequel in which we deal instead with generalizations of \emph{wrinkled submersions}. The main messages are that: 1) Haefliger structures provide a nice conceptual framework in which general wrinkling statements can be made. 2) Wrinkling can be interpreted as holonomic approximation into the \'etale space of solutions of the relation $\mathcal{R}$. These statements imply connectivity statements relating (1) $\mathcal{R}$ to its \'etale space of solutions and (2) the classifying space for foliations with transverse $\mathcal{R}$-geometry to its formal counterpart.