Lyot-plane phase masks for improved high-contrast imaging with a vortex coronagraph

TL;DR

This paper introduces a Lyot-plane phase mask for vortex coronagraphs, enhancing high-contrast imaging capabilities for telescopes with complex apertures, especially for exoplanet detection.

Contribution

The novel phase-only Lyot-plane optic improves starlight suppression in vortex coronagraphs for obstructed telescopes, demonstrating superior contrast performance.

Findings

Achieves contrast of ~10^{-6} for small angular displacements

Reduces stellar noise by relocating residual starlight

Improves performance even with optical aberrations

Abstract

The vortex coronagraph is an optical instrument that precisely removes on-axis starlight allowing for high contrast imaging at small angular separation from the star, thereby providing a crucial capability for direct detection and characterization of exoplanets and circumstellar disks. Telescopes with aperture obstructions, such as secondary mirrors and spider support structures, require advanced coronagraph designs to provide adequate starlight suppression. We introduce a phase-only Lyot-plane optic to the vortex coronagraph that offers improved contrast performance on telescopes with complicated apertures. Potential solutions for the European Extremely Large Telescope (E-ELT) are described and compared. Adding a Lyot-plane phase mask relocates residual starlight away from a region of the image plane thereby reducing stellar noise and improving sensitivity to off-axis companions. The phase mask is calculated using an iterative phase retrieval algorithm. Numerically, we achieve a contrast on the order of $10^{-6}$ for a companion with angular displacement as small as $4~\lambda/D$ with an E-ELT type aperture. Even in the presence of aberrations, improved performance is expected compared to either a conventional vortex coronagraph or optimized pupil plane phase element alone.