Curves and surfaces making a constant angle with a parallel transported direction in Riemannian spaces

Luiz C. B. da Silva, Gilson S. Ferreira Jr, José D. da Silva

Research output: Working paper/PreprintPreprint

20 Downloads (Pure)

Abstract

In the last two decades, much effort has been dedicated to studying curves and surfaces according to their angle with a given direction. How- ever, most findings were obtained using a case-by-case approach, and it is often unclear what is a consequence of specificities of the ambient manifold and what could be generic. In this work, we propose a theo- retical framework to unify parts of these findings. We study curves and surfaces by prescribing the angle they make with a parallel transported vector field. We show that the characterization of Euclidean helices in terms of their curvature and torsion is also valid in any Riemannian manifold. Among other properties, we prove that surfaces making a con- stant angle with a parallel transported direction are extrinsically flat ruled surfaces. We also investigate the relation between their geodesics and the so-called slant helices. We prove that surfaces of constant angle are the rectifying surface of a slant helix, i.e., the ruled surface with rulings given by the Darboux field of the directrix. We characterize recti- fying surfaces of constant angle or, equivalently, when their geodesics are slant helices. As a corollary, we show that if every geodesic of a surface of constant angle is a slant helix, the ambient manifold is flat. Finally, we characterize surfaces in the product of a Riemannian surface with the real line making a constant angle with the vertical real direction.
Original languageEnglish
PublisherarXiv
Pages1-27
Number of pages27
DOIs
Publication statusPublished - 15 Mar 2024

Keywords

  • Helix
  • Slant helix
  • Surface of constant angle
  • Rectifying surface

Fingerprint

Dive into the research topics of 'Curves and surfaces making a constant angle with a parallel transported direction in Riemannian spaces'. Together they form a unique fingerprint.

Cite this