L'-band AGPM vector vortex coronagraph's first light on VLT/NACO. Discovery of a late-type companion

Context. High contrast imaging has thoroughly combed through the limited search space accessible with first-generation ground-based adaptive optics instruments and the Hubble Space Telescope. Only a few objects were discovered, and many non-detections reported and statistically interpreted. The field is now in need of a technological breakthrough. Aims. Our aim is to open a new search space with first-generation systems such as NACO at the Very Large Telescope, by providing ground-breaking inner working angle (IWA) capabilities in the L′ band. The L′ band is a sweet spot for high contrast coronagraphy since the planet-to-star brightness ratio is favorable, while the Strehl ratio is naturally higher. Methods. An annular groove phase mask (AGPM) vector vortex coronagraph optimized for the L′ band made from diamond subwavelength gratings was manufactured and qualified in the lab. The AGPM enables high contrast imaging at very small IWA, potentially being the key to unexplored discovery space. Results. Here we present the installation and successful on-sky tests of an L'-band AGPM coronagraph on NACO. Using angular differential imaging, which is well suited to the rotational symmetry of the AGPM, we demonstrated a ΔL′ > 7.5 mag contrast from an IWA ≃ 0."09 onwards, during average seeing conditions, and for total integration times of a few hundred seconds.

[1]  P. H. Hauschildt,et al.  Evolutionary models for cool brown dwarfs and extrasolar giant planets. The case of HD 209458 , 2003 .

[2]  A. Boccaletti,et al.  The Four‐Quadrant Phase Mask Coronagraph. IV. First Light at the Very Large Telescope , 2004 .

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

[4]  B. Macintosh,et al.  Angular Differential Imaging: A Powerful High-Contrast Imaging Technique , 2005, astro-ph/0512335.

[5]  E. Hatziminaoglou,et al.  Star counts in the Galaxy - Simulating from very deep to very shallow photometric surveys with the TRILEGAL code , 2005, astro-ph/0504047.

[6]  Markus Janson,et al.  A novel L-band imaging search for giant planets in the Tucana and β Pictoris moving groups , 2007, 0706.0095.

[7]  B. Oppenheimer,et al.  The Gemini Deep Planet Survey , 2007, 0705.4290.

[8]  Mark S. Marley,et al.  Synthetic Spectra and Colors of Young Giant Planet Atmospheres: Effects of Initial Conditions and Atmospheric Metallicity , 2008, 0805.1066.

[9]  C. Marois,et al.  Confidence Level and Sensitivity Limits in High-Contrast Imaging , 2007, 0709.3548.

[10]  D. Mawet,et al.  Formation and evolution of planetary systems: the impact of high-angular resolution optical techniques , 2009, 0912.3915.

[11]  The Geneva-Copenhagen survey of the solar neighbourhood III. Improved distances, ages, and kinematics , 2008, 0811.3982.

[12]  Norbert Hubin,et al.  Adaptive Optics Systems II , 2010 .

[13]  Julien H. Girard,et al.  FIRST RESULTS FROM VERY LARGE TELESCOPE NACO APODIZING PHASE PLATE: 4 μm IMAGES OF THE EXOPLANET β PICTORIS b , 2010, 1009.0538.

[14]  Deep imaging survey of young, nearby austral stars - VLT/NACO near-infrared Lyot-coronographic observations , 2010 .

[15]  John Asher Johnson,et al.  ESTIMATES OF THE PLANET YIELD FROM GROUND-BASED HIGH-CONTRAST IMAGING OBSERVATIONS AS A FUNCTION OF STELLAR MASS , 2011, 1103.4910.

[16]  A. Vigan,et al.  The International Deep Planet Survey - I. The frequency of wide-orbit massive planets around A-stars , 2012, 1206.4048.

[17]  Adam Burrows,et al.  SPECTRAL AND PHOTOMETRIC DIAGNOSTICS OF GIANT PLANET FORMATION SCENARIOS , 2011, 1108.5172.

[18]  S. Quanz,et al.  Direct imaging constraints on planet populations detected by microlensing , 2012, 1203.3647.

[19]  Julien H. Girard,et al.  Gearing up the SPHERE , 2012 .

[20]  R. Soummer,et al.  DETECTION AND CHARACTERIZATION OF EXOPLANETS AND DISKS USING PROJECTIONS ON KARHUNEN–LOÈVE EIGENIMAGES , 2012, 1207.4197.

[21]  F. B. Amara,et al.  Adaptive Optics Systems , 2013 .

[22]  Pontus Forsberg,et al.  High aspect ratio optical gratings in diamond , 2013 .

[23]  Julien H. Girard,et al.  CORONAGRAPHIC OBSERVATIONS OF FOMALHAUT AT SOLAR SYSTEM SCALES , 2012, 1212.1459.

[24]  D. Mawet,et al.  Laboratory demonstration of a mid-infrared AGPM vector vortex coronagraph , 2013, 1304.1180.

[25]  Pontus Forsberg,et al.  Inclined surfaces in diamond: broadband antireflective structures and coupling light through waveguides. , 2013, Optics express.