Performance and sensitivity of vortex coronagraphs on segmented space telescopes

TL;DR

This paper evaluates the performance and sensitivity of apodized vortex coronagraphs for segmented space telescopes, focusing on their ability to suppress starlight and detect exoplanets despite optical aberrations.

Contribution

It analyzes the sensitivity of vortex coronagraphs to various aberrations and identifies suitable designs and telescope requirements for future missions like HabEx and LUVOIR.

Findings

Vortex coronagraphs can achieve high contrast with segmented telescopes.

Sensitivity to segment co-phasing errors impacts coronagraph performance.

Designs are proposed for specific telescope architectures.

Abstract

The detection of molecular species in the atmospheres of earth-like exoplanets orbiting nearby stars requires an optical system that suppresses starlight and maximizes the sensitivity to the weak planet signals at small angular separations. Achieving sufficient contrast performance on a segmented aperture space telescope is particularly challenging due to unwanted diffraction within the telescope from amplitude and phase discontinuities in the pupil. Apodized vortex coronagraphs are a promising solution that theoretically meet the performance needs for high contrast imaging with future segmented space telescopes. We investigate the sensitivity of apodized vortex coronagraphs to the expected aberrations, including segment co-phasing errors in piston and tip/tilt as well as other low-order and mid-spatial frequency aberrations. Coronagraph designs and their associated telescope requirements are identified for conceptual HabEx and LUVOIR telescope designs.