Active minimization of non-common path aberrations in long-exposure imaging of exoplanetary systems

TL;DR

This paper demonstrates an active method using the self-coherent camera to minimize quasi-static speckles caused by non-common path aberrations in long-exposure exoplanet imaging, improving contrast in simulated ground conditions.

Contribution

The study introduces a laboratory demonstration of the self-coherent camera's ability to actively reduce quasi-static speckles in long-exposure imaging, addressing a key limitation in current exoplanet direct imaging instruments.

Findings

Achieved contrast levels below 10^{-6} in laboratory conditions.

Demonstrated the SCC's effectiveness in minimizing quasi-static speckles.

Limitations set by AO halo residuals in speckle suppression.

Abstract

Context. Spectroscopy of exoplanets is very challenging because of the high star-planet contrast. A technical difficulty in the design of imaging instruments is the noncommon path aberrations (NCPAs) between the adaptive optics (AO) sensing and the science camera, which induce planet-resembling stellar speckles in the coronagraphic science images. In an observing sequence of several long exposures, quickly evolving NCPAs average out and leave behind an AO halo that adds photon noise to the planet detection. Static NCPA can be calibrated a posteriori using differential imaging techniques. However, NCPAs that evolve during the observing sequence do not average out and cannot be calibrated a posteriori. These quasi-static NCPAs are one of the main limitations of the current direct imaging instruments such as SPHERE, GPI, and SCExAO. Aims. Our aim is to actively minimize the quasi-static speckles induced in long-exposure images. To do so, we need to measure the quasi-static speckle field above the AO halo. Methods. The self-coherent camera (SCC) is a proven technique which measures the speckle complex field in the coronagraphic science images. It is routinely used on the THD2 bench to reach contrast levels of <10^{-8} in the range 5-12 {\lambda}/D in space-related conditions. To test the SCC in ground conditions on THD2, we optically simulated the residual aberrations measured behind the SPHERE/VLT AO system under good observing conditions. Results. We demonstrate in the laboratory that the SCC can minimize the quasi-static speckle intensity in the science images down to a limitation set by the AO halo residuals. The SCC reaches 1{\sigma} raw contrast levels below 10^{-6} in the region 5-12 {\lambda}/D at 783.25 nm in our experiments.