Calibration of the island effect: Experimental validation of closed-loop focal plane wavefront control on Subaru/SCExAO

Island effect (IE) aberrations are induced by differential pistons, tips, and tilts between neighboring pupil segments on ground-based telescopes, which severely limit the observations of circumstellar environments on the recently deployed exoplanet imagers (e.g., VLT/SPHERE, Gemini/GPI, Subaru/SCExAO) during the best observing conditions. Caused by air temperature gradients at the level of the telescope spiders, these aberrations were recently diagnosed with success on VLT/SPHERE, but so far no complete calibration has been performed to overcome this issue. We propose closed-loop focal plane wavefront control based on the asymmetric Fourier pupil wavefront sensor (APF-WFS) to calibrate these aberrations and improve the image quality of exoplanet high-contrast instruments in the presence of the IE. Assuming the archetypal four-quadrant aperture geometry in 8m class telescopes, we describe these aberrations as a sum of the independent modes of piston, tip, and tilt that are distributed in each quadrant of the telescope pupil. We calibrate these modes with the APF-WFS before introducing our wavefront control for closed-loop operation. We perform numerical simulations and then experimental tests on a real system using Subaru/SCExAO to validate our control loop in the laboratory and on-sky. Closed-loop operation with the APF-WFS enables the compensation for the IE in simulations and in the laboratory for the small aberration regime. Based on a calibration in the near infrared, we observe an improvement of the image quality in the visible range on the SCExAO/VAMPIRES module with a relative increase in the image Strehl ratio of 37%. Our first IE calibration paves the way for maximizing the science operations of the current exoplanet imagers. Such an approach and its results prove also very promising in light of the Extremely Large Telescopes (ELTs) and the presence of similar artifacts.

[1]  T. Fusco,et al.  Calibration of quasi-static aberrations in exoplanet direct-imaging instruments with a Zernike phase-mask sensor. II. Concept validation with ZELDA on VLT/SPHERE , 2016, 1606.01895.

[2]  Kjetil Dohlen,et al.  On-sky multiwavelength phasing of segmented telescopes with the Zernike phase contrast sensor. , 2011, Applied optics.

[3]  C. Moutou,et al.  High-contrast imaging of Sirius A with VLT/SPHERE: looking for giant planets down to one astronomical unit , 2015, 1509.00015.

[4]  Pierre Baudoz,et al.  Post-coronagraphic tip-tilt sensing for vortex phase masks: The QACITS technique , 2015, 1509.06158.

[5]  Julien H. Girard,et al.  Discovery of a warm, dusty giant planet around HIP 65426 , 2017, 1707.01413.

[6]  Ben R. Oppenheimer,et al.  High-Contrast Observations in Optical and Infrared Astronomy , 2009 .

[7]  Gautam Vasisht,et al.  Characterizing 51 Eri b from 1 to 5 μm: A Partly Cloudy Exoplanet , 2017, 1705.03887.

[8]  Andrew Serio,et al.  THE FIRST H-BAND SPECTRUM OF THE GIANT PLANET β PICTORIS b , 2014, 1407.4469.

[9]  Frantz Martinache,et al.  The Asymmetric Pupil Fourier Wavefront Sensor , 2013, 1303.6678.

[10]  Frantz Martinache,et al.  A Demonstration of Wavefront Sensing and Mirror Phasing from the Image Domain , 2014, 1401.7566.

[11]  Kjetil Dohlen,et al.  Fast-moving features in the debris disk around AU Microscopii , 2015, Nature.

[12]  Dmitry Savransky,et al.  Computer vision applications for coronagraphic optical alignment and image processing. , 2013, Applied optics.

[13]  Jan Swevers,et al.  Ground-based and airborne instrumentation for astronomy , 2010 .

[14]  Thierry Fusco,et al.  Calibration and precompensation of noncommon path aberrations for extreme adaptive optics. , 2007, Journal of the Optical Society of America. A, Optics, image science, and vision.

[15]  G. Perrin,et al.  The Subaru Coronagraphic Extreme Adaptive Optics System: Enabling High-Contrast Imaging on Solar-System Scales , 2015, 1507.00017.

[16]  E. Nesvold,et al.  A SMACK MODEL OF COLLIDING PLANETESIMALS IN THE β PICTORIS DEBRIS DISK , 2015, 1506.07187.

[17]  Frantz Martinache,et al.  Closed-loop focal plane wavefront control with the SCExAO instrument , 2016, 1604.08787.

[18]  O. Guyon,et al.  The VAMPIRES instrument: imaging the innermost regions of protoplanetary discs with polarimetric interferometry , 2014, 1405.7426.

[19]  G Rousset,et al.  High-order adaptive optics requirements for direct detection of extrasolar planets: Application to the SPHERE instrument. , 2006, Optics express.

[20]  Pierre Baudoz,et al.  Self-coherent camera as a focal plane wavefront sensor: simulations , 2009, 0911.2465.

[21]  Julien Lozi,et al.  Subaru/SCExAO First-light Direct Imaging of a Young Debris Disk around HD 36546 , 2017 .

[22]  Jean-Louis Lizon,et al.  The differential tip-tilt sensor of SPHERE , 2010, Astronomical Telescopes + Instrumentation.

[23]  A. Couder Sur un Effet Thermique: Observé dans les Télescopes a Réflexion , 1949 .

[24]  Brendan P. Bowler,et al.  Imaging Extrasolar Giant Planets , 2016, 1605.02731.

[25]  Frantz Martinache Spectrally dispersed Fourier-phase analysis for redundant apertures , 2016, Astronomical Telescopes + Instrumentation.

[26]  P. Tuthill,et al.  Michelson Interferometry with the Keck I Telescope , 2000 .

[27]  Andrew W. Serio,et al.  First light of the Gemini Planet Imager , 2014, Proceedings of the National Academy of Sciences.

[28]  Frantz Martinache,et al.  On-sky demonstration of low-order wavefront sensing and control with focal plane phase mask coronagraphs , 2015 .

[29]  A. Vigan,et al.  Spectral and atmospheric characterization of 51 Eridani b using VLT/SPHERE , 2017, 1704.02987.

[30]  I. McLean,et al.  Ground-based and Airborne Instrumentation for Astronomy , 2006 .

[31]  Jean-Pierre Véran,et al.  Quantifying telescope phase discontinuities external to adaptive optics systems by use of phase diversity and focal plane sharpening , 2017 .

[32]  L. Mugnier,et al.  Coronagraphic phase diversity: performance study and laboratory demonstration , 2013, 1303.0121.

[33]  Ruobing Dong,et al.  What is the Mass of a Gap-Opening Planet? , 2016, 1612.04821.