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Near-infrared scattered light properties of the HR 4796 A dust ring A measured scattering phase function from 13.6° to 166.6°

Milli, J. and Mawet, D. and Schlieder, J. E. (2017) Near-infrared scattered light properties of the HR 4796 A dust ring A measured scattering phase function from 13.6° to 166.6°. Astronomy & Astrophysics, 599 . Art. No. A108. ISSN 0004-6361. doi:10.1051/0004-6361/201527838.

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Context. HR 4796 A is surrounded by a debris disc, observed in scattered light as an inclined ring with a high surface brightness. Past observations have raised several questions. First, a strong brightness asymmetry detected in polarised reflected light has recently challenged our understanding of scattering by the dust particles in this system. Secondly, the morphology of the ring strongly suggests the presence of planets, although no planets have been detected to date. Aims. We aim here at measuring with high accuracy the morphology and photometry of the ring in scattered light, in order to derive the phase function of the dust and constrain its near-infrared spectral properties. We also want to constrain the presence of planets and set improved constraints on the origin of the observed ring morphology. Methods. We obtained high-angular resolution coronagraphic images of the circumstellar environment around HR 4796 A with VLT/SPHERE during the commissioning of the instrument in May 2014 and during guaranteed-time observations in February 2015. The observations reveal for the first time the entire ring of dust, including the semi-minor axis that was previously hidden either behind the coronagraphic spot or in the speckle noise. Results. We determine empirically the scattering phase function of the dust in the H band from 13.6° to 166.6°. It shows a prominent peak of forward scattering, never detected before, for scattering angles below 30°. We analyse the reflectance spectra of the disc from the 0.95 μm to 1.6 μm, confirming the red colour of the dust, and derive detection limits on the presence of planetary mass objects. Conclusions. We confirm which side of the disc is inclined towards the Earth. The analysis of the phase function, especially below 45°, suggests that the dust population is dominated by particles much larger than the observation wavelength, of about 20 μm. Compact Mie grains of this size are incompatible with the spectral energy distribution of the disc, however the observed rise in scattering efficiency beyond 50° points towards aggregates which could reconcile both observables. We do not detect companions orbiting the star, but our high-contrast observations provide the most stringent constraints yet on the presence of planets responsible for the morphology of the dust.

Item Type:Article
Related URLs:
URLURL TypeDescription Paper
Milli, J.0000-0001-9325-2511
Mawet, D.0000-0002-8895-4735
Schlieder, J. E.0000-0001-5347-7062
Additional Information:© 2017 ESO. Received: 26 November 2015. Accepted: 16 December 2016. J.M. acknowledges financial support from the ESO fellowship programme. A.M.L. acknowledges the support from the ANR blanche GIPSE (ANR-14-CE33-0018) and the Labex OSUG. L.M. acknowledges support by STFC and ESO through graduate studentships and by the European Union through ERC grant number 279973. We would like to thank ESO staff and technical operators at the Paranal Observatory. We thank M. Meyer and D. Rouan for their valueable suggestions and comments during the review by the SPHERE internal board. We thank P. Delorme and E. Lagadec (SPHERE Data Center) for their work during the data reduction process. We thank V. Faramaz for the discussion on the eccentricity of the disc. SPHERE is an instrument designed and built by a consortium consisting of IPAG (Grenoble, France), MPIA (Heidelberg, Germany), LAM (Marseille, France), LESIA (Paris, France), Laboratoire Lagrange (Nice, France), INAF – Osservatorio di Padova (Italy), Observatoire de Genève (Switzerland), ETH Zurich (Switzerland), NOVA (Netherlands), ONERA (France) and ASTRON (Netherlands) in collaboration with ESO. SPHERE was funded by ESO, with additional contributions from CNRS (France), MPIA (Germany), INAF (Italy), FINES (Switzerland) and NOVA (Netherlands). SPHERE also received funding from the European Commission Sixth and Seventh Framework Programmes as part of the Optical Infrared Coordination Network for Astronomy (OPTICON) under grant number RII3-Ct-2004-001566 for FP6 (2004–2008), grant number 226604 for FP7 (2009–2012) and grant number 312430 for FP7 (2013–2016).
Group:Astronomy Department
Funding AgencyGrant Number
European Southern Observatory (ESO)UNSPECIFIED
Agence Nationale pour la Recherche (ANR)ANR-14-CE33-0018
Science and Technology Facilities Council (STFC)UNSPECIFIED
European Research Council (ERC)279973
Centre National de la Recherche Scientifique (CNRS)UNSPECIFIED
Max Planck Institute for Astronomy (MPIA)UNSPECIFIED
Istituto Nazionale di Astrofisica (INAF)UNSPECIFIED
Nederlandse Onderzoekschool voor de Astronomie (NOVA)UNSPECIFIED
European CommissionRII3-Ct-2004-001566
European Research Council (ERC)226604
European Research Council (ERC)312430
Subject Keywords:instrumentation: high angular resolution, planet-disk interactions, planets and satellites: detection, scattering, planetary systems
Record Number:CaltechAUTHORS:20170417-093723203
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Official Citation:Near-infrared scattered light properties of the HR 4796 A dust ring - A measured scattering phase function from 13.6° to 166.6° J. Milli, A. Vigan, D. Mouillet, A.-M. Lagrange, J.-C. Augereau, C. Pinte, D. Mawet, H. M. Schmid, A. Boccaletti, L. Matrà, Q. Kral, S. Ertel, G. Chauvin, A. Bazzon, F. Ménard, J.-L. Beuzit, C. Thalmann, C. Dominik, M. Feldt, T. Henning, M. Min, J. H. Girard, R. Galicher, M. Bonnefoy, T. Fusco, J. de Boer, M. Janson, A.-L. Maire, D. Mesa, J. E. Schlieder and the SPHERE Consortium A&A, 599 (2017) A108 DOI:
Usage Policy:No commercial reproduction, distribution, display or performance rights in this work are provided.
ID Code:76591
Deposited By: Ruth Sustaita
Deposited On:17 Apr 2017 17:32
Last Modified:15 Nov 2021 17:01

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