Imaging exoplanets with coronagraphic instruments

TL;DR

This paper reviews the principles, challenges, and techniques of coronagraphic imaging for exoplanets, focusing on instrument subsystems, wavefront aberrations, and speckle mitigation methods to enhance direct detection capabilities.

Contribution

It provides a comprehensive overview of coronagraphic methods, including formalism, aberration effects, and calibration techniques, tailored for non-specialists and newcomers.

Findings

Coronagraphs can suppress stellar light to reveal exoplanets.

Wavefront aberrations induce speckles that hinder imaging performance.

Calibration techniques improve the contrast and detection sensitivity.

Abstract

Exoplanetary science is a very active field of astronomy nowadays, with questions still opened such as how planetary systems form and evolve (occurrence, process), why such a diversity of exoplanets is observed (mass, radius, orbital parameters, temperature, composition), and what are the interactions between planets, circumstellar disk and their host star. Several complementary methods are used for the detection of exoplanets. Among these, imaging aims at the direct detection of the light reflected, scattered or emitted by exoplanets and circumstellar disks. This allows their spectral and polarimetric characterization. Such imaging remains challenging because of the large luminosity ratio (1e4-1e10$) and the small angular separation (fraction of an arcsecond) between the star and its environment. Over the past two decades, numerous techniques, including coronagraphy, have been developed to make exoplanet imaging a reality. This review gives a broad overview of the subsystems that make up a coronagraphic instrument for imaging exoplanetary systems. It is especially intended for non-specialists or newcomers in the field. We explain the principle of coronagraphy and propose a formalism to understand their behavior. We discuss the impact of wavefront aberrations on the performance of coronagraphs and how they induce stellar speckles in the scientific image. Finally, we present instrumental and signal processing techniques used for on-sky minimization or a posteriori calibration of these speckles in order to improve the performance of coronagraphs.