A construction of constant mean curvature surfaces in $\mathbb{H}^2\times\mathbb{R}$ and the Krust property

TL;DR

This paper constructs a family of constant mean curvature surfaces in hyperbolic product space, explores their properties, introduces new examples called $(H,k)$-nodoids, and shows the Krust property fails for all positive mean curvatures.

Contribution

The paper introduces a 2-parameter family of constant mean curvature surfaces in ${ m H}^2 imes m R$, including new examples called $(H,k)$-nodoids, and analyzes their geometric properties and conjugate surfaces.

Findings

Existence of symmetric, properly embedded CMC surfaces extending minimal saddle towers and $k$-noids.

Introduction of $(H,k)$-nodoids with asymptotic behavior over geodesic curvature curves.

Proof that the Krust property does not hold for any $H>0$ in these contexts.

Abstract

We show the existence of a $2$-parameter family of properly Alexandrov-embedded surfaces with constant mean curvature $0\leq H\leq\frac{1}{2}$ in ${\mathbb{H}^2\times\mathbb{R}}$. They are symmetric with respect to a horizontal slice and a $k$ vertical planes disposed symmetrically, and extend the so called minimal saddle towers and $k$-noids. We show that the orientation plays a fundamental role when $H>0$ by analyzing their conjugate minimal surfaces in $\widetilde{\mathrm{SL}}_2(\mathbb{R})$ or $\mathrm{Nil}_3$. We also discover new complete examples that we call $(H,k)$-nodoids, whose $k$ ends are asymptotic to vertical cylinders over curves of geodesic curvature $2H$ from the convex side, often giving rise to non-embedded examples if $H>0$. In the discussion of embeddedness of the constructed examples, we prove that the Krust property does not hold for any $H>0$, i.e., there are minimal graphs over convex domains in $\widetilde{\mathrm{SL}}_2(\mathbb{R})$, $\mathrm{Nil}_3$ or the Berger spheres, whose conjugate surfaces with constant mean curvature $H$ in $\mathbb{H}^2\times\mathbb{R}$ are not graphs.