Simulations of a high-contrast single-mode fiber coronagraphic multiobject spectrograph for future space telescopes

Directly imaging and characterizing Earth-like exoplanets is a tremendously difficult instrumental challenge. Present coronagraphic systems have yet to achieve the required $10^{-10}$ broadband contrast in a laboratory environment, but promising progress towards this goal continues. A new approach to starlight suppression is the use of a single-mode fiber behind a coronagraph. By using deformable mirrors to create a mismatch between incoming starlight and the fiber mode, a single-mode fiber can be turned into an integral part of the starlight suppression system. In this paper, we present simulation results of a system with five single-mode fibers coupled to shaped pupil and vortex coronagraphs. We investigate the properties of the system, including its spectral bandwidth, throughput, and sensitivity to low-order aberrations. We also compare the performance of the single-mode fiber configuration with conventional imaging and multi-object modes, finding improved spectral bandwidth, raw contrast, background-limited SNR, and demonstrate a wavefront control algorithm which is robust to tip/tilt errors.

[1]  Luc B. Jeunhomme Single-mode fiber optics: Principles and applications , 1983 .

[2]  F. Roddier,et al.  Coupling starlight into single-mode fiber optics. , 1988, Applied optics.

[3]  W. Traub,et al.  A Coronagraph with a Band-limited Mask for Finding Terrestrial Planets , 2002, astro-ph/0203455.

[4]  R. Vanderbei,et al.  Extrasolar Planet Finding via Optimal Apodized-Pupil and Shaped-Pupil Coronagraphs , 2003 .

[5]  S. Ridgway,et al.  Exoplanet Imaging with a Phase-induced Amplitude Apodization Coronagraph. I. Principle , 2004, astro-ph/0412179.

[6]  Scot S. Olivier,et al.  Extrasolar Planetary Imaging Coronagraph (EPIC) , 2004, SPIE Astronomical Telescopes + Instrumentation.

[7]  D. Mawet,et al.  Annular Groove Phase Mask Coronagraph , 2005 .

[8]  R. Soummer Apodized Pupil Lyot Coronagraphs for Arbitrary Telescope Apertures , 2004, astro-ph/0412221.

[9]  G. Swartzlander,et al.  Optical vortex coronagraph. , 2005, Optics letters.

[10]  Amir Give'on,et al.  Broadband wavefront correction algorithm for high-contrast imaging systems , 2007, SPIE Optical Engineering + Applications.

[11]  W. Traub,et al.  A laboratory demonstration of the capability to image an Earth-like extrasolar planet , 2007, Nature.

[12]  John E. Krist,et al.  A hybrid Lyot coronagraph for the direct imaging and spectroscopy of exoplanet systems: recent results and prospects , 2011, Optical Engineering + Applications.

[13]  Frantz Martinache,et al.  Laboratory demonstration of Phase Induced Amplitude Apodization (PIAA) coronagraph with better than 10-9 contrast , 2013, Optics & Photonics - Optical Engineering + Applications.

[14]  J. Krist,et al.  D-92350 TECHNOLOGY DEVELOPMENT FOR EXOPLANET MISSONS Technology Milestone # 1 Report : Vortex Coronagraph Technology , 2014 .

[15]  Remko Stuik,et al.  Combining high-dispersion spectroscopy with high contrast imaging : Probing rocky planets around our nearest neighbors , 2015, 1503.01136.

[16]  Jeffrey Jewell,et al.  Apodized vortex coronagraph designs for segmented aperture telescopes , 2016, Astronomical Telescopes + Instrumentation.

[17]  Robert J. Vanderbei,et al.  Lyot coronagraph design study for large, segmented space telescope apertures , 2016, Astronomical Telescopes + Instrumentation.

[18]  Mamadou N'Diaye,et al.  APODIZED PUPIL LYOT CORONAGRAPHS FOR ARBITRARY APERTURES. V. HYBRID SHAPED PUPIL DESIGNS FOR IMAGING EARTH-LIKE PLANETS WITH FUTURE SPACE OBSERVATORIES , 2016, 1601.02614.

[19]  Olivier Guyon,et al.  The Habitable Exoplanet (HabEx) Imaging Mission: preliminary science drivers and technical requirements , 2016, Astronomical Telescopes + Instrumentation.

[20]  D. Mawet,et al.  Observing Exoplanets with High-dispersion Coronagraphy. II. Demonstration of an Active Single-mode Fiber Injection Unit , 2017, 1703.00583.

[21]  Kevin France,et al.  The Large UV/Optical/Infrared Surveyor (LUVOIR): Decadal Mission concept design update , 2017, Optical Engineering + Applications.

[22]  Dimitri Mawet,et al.  Observing Exoplanets with High Dispersion Coronagraphy. I. The Scientific Potential of Current and Next-generation Large Ground and Space Telescopes , 2017, 1703.00582.

[23]  Jacques-Robert Delorme,et al.  Wavefront control for minimization of speckle coupling into a fiber injection unit based on the electric field conjugation algorithm , 2018, Astronomical Telescopes + Instrumentation.

[24]  G. Ruane,et al.  Fast linearized coronagraph optimizer (FALCO) IV: coronagraph design survey for obstructed and segmented apertures , 2018, Astronomical Telescopes + Instrumentation.

[25]  Stuart B. Shaklan,et al.  Fast linearized coronagraph optimizer (FALCO) I: a software toolbox for rapid coronagraphic design and wavefront correction , 2018, Astronomical Telescopes + Instrumentation.

[26]  Ji Wang,et al.  Effects of thermal and exozodiacal background on space telescope observations of exoEarths , 2018, Astronomical Telescopes + Instrumentation.

[27]  Mamadou N'Diaye,et al.  Optimal deformable mirror and pupil apodization combinations for apodized pupil Lyot coronagraphs with obstructed pupils , 2018, Astronomical Telescopes + Instrumentation.

[28]  Brian Kern,et al.  Fast linearized coronagraph optimizer (FALCO) III: optimization of key coronagraph design parameters , 2018, Astronomical Telescopes + Instrumentation.

[29]  Jacques-Robert Delorme,et al.  Demonstration of an electric field conjugation algorithm for improved starlight rejection through a single mode optical fiber , 2019, Journal of Astronomical Telescopes, Instruments, and Systems.

[30]  M. Kenworthy,et al.  The Single-mode Complex Amplitude Refinement (SCAR) coronagraph , 2018, Astronomy & Astrophysics.