4.7 Article

Interferometric apodization by homothety - I. Optimization of the device parameters

Journal

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY
Volume 523, Issue 4, Pages 5442-5451

Publisher

OXFORD UNIV PRESS
DOI: 10.1093/mnras/stad1743

Keywords

instrumentation: high angular resolution; instrumentation: interferometers; techniques: high angular resolution; techniques: interferometric

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This study focuses on high dynamic imaging, specifically the direct observation of exoplanetary systems. The use of a coronagraph is essential for suppressing the star's light and detecting the faint exoplanet. This study presents an apodization method using interferometry with either a rectangular or circular aperture, achieving a high concentration rate of light energy and enhancing the performance of a coronagraph.
This study is focused on the very high dynamic imaging field, specifically the direct observation of exoplanetary systems. The coronagraph is an essential technique for suppressing the star's light, making it possible to detect an exoplanet with a very weak luminosity compared to its host star. Apodization improves the rejection of the coronagraph, thereby increasing its sensitivity. This work presents the apodization method by interferometry using homothety, with either a rectangular or circular aperture. We discuss the principle method, the proposed experimental set-up, and present the obtained results by optimizing the free parameters of the system while concentrating the maximum of the light energy in the central diffraction lobe, with a concentration rate of 93.6 per cent for the circular aperture and 91.5 per cent for the rectangular geometry. The obtained results enabled scaling the various elements of the experiment in accordance with practical constraints. Simulation results are presented for both circular and rectangular apertures. We performed simulations on a hexagonal aperture, both with and without a central obstruction, as well as a segmented aperture similar to the one used in the Thirty Meter Telescope (TMT). This approach enables the attainment of a contrast of approximately 10(-4) at small angular separations, specifically around 1.8 & lambda;/D. When integrated with a coronagraph, this technique exhibits great promise. These findings confirm that our proposed technique can effectively enhance the performance of a coronagraph.

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