Ring-apodized vortex coronagraphs for obscured telescopes. I. Transmissive ring apodizers

TL;DR

This paper introduces a ring-apodized vortex coronagraph (RAVC) that effectively overcomes diffraction issues caused by central obscurations in telescopes, maintaining high contrast and throughput for imaging exoplanets.

Contribution

The paper presents a novel ring apodizer design that restores vortex coronagraph performance for obscured telescopes, preserving contrast and inner working angle.

Findings

RAVC achieves perfect attenuation regardless of central obscuration size.

The design maintains the vortex coronagraph's inner working angle.

High throughput is preserved with the RAVC approach.

Abstract

The vortex coronagraph (VC) is a new generation small inner working angle (IWA) coronagraph currently offered on various 8-meter class ground-based telescopes. On these observing platforms, the current level of performance is not limited by the intrinsic properties of actual vortex devices, but by wavefront control residuals and incoherent background (e.g. thermal emission of the sky) or the light diffracted by the imprint of the secondary mirror and support structures on the telescope pupil. In the particular case of unfriendly apertures (mainly large central obscuration) when very high contrast is needed (e.g. direct imaging of older exoplanets with extremely large telescopes or space- based coronagraphs), a simple VC, as most coronagraphs, can not deliver its nominal performance because of the contamination due to the diffraction from the obscured part of the pupil. Here we propose a novel yet simple concept that circumvents this problem. We combine a vortex phase mask in the image plane of a high-contrast instrument with a single pupil-based amplitude ring apodizer, tailor designed to exploit the unique convolution properties of the VC at the Lyot-stop plane. We show that such a ring-apodized vortex coronagraph (RAVC) restores the perfect attenuation property of the VC regardless of the size of the central obscuration, and for any (even) topological charge of the vortex. More importantly the RAVC maintains the IWA and conserves a fairly high throughput, which are signature properties of the VC.