Your search keyword '"Flasseur, O."' showing total 7 results

1. An imaged 15 MJup companion within a hierarchical quadruple system

Author

Chomez, A., primary, Squicciarini, V., additional, Lagrange, A.-M., additional, Delorme, P., additional, Viswanath, G., additional, Janson, M., additional, Flasseur, O., additional, Chauvin, G., additional, Langlois, M., additional, Rubini, P., additional, Bergeon, S., additional, Albert, D., additional, Bonnefoy, M., additional, Desidera, S., additional, Engler, N., additional, Gratton, R., additional, Henning, T., additional, Mamajek, E. E., additional, Marleau, G.-D., additional, Meyer, M. R., additional, Reffert, S., additional, Ringqvist, S. C., additional, and Samland, M., additional

Published

2023

2. Preparation for an unsupervised massive analysis of SPHERE high-contrast data with PACO. Optimization and benchmarking on 24 solar-type stars

Author

Chomez, A., primary, Lagrange, A.-M., additional, Delorme, P., additional, Langlois, M., additional, Chauvin, G., additional, Flasseur, O., additional, Dallant, J., additional, Philipot, F., additional, Bergeon, S., additional, Albert, D., additional, Meunier, N., additional, and Rubini, P., additional

Published

2023

3. A scaled-up planetary system around a supernova progenitor

Author

Squicciarini, V., primary, Gratton, R., additional, Janson, M., additional, Mamajek, E. E., additional, Chauvin, G., additional, Delorme, P., additional, Langlois, M., additional, Vigan, A., additional, Ringqvist, S. C., additional, Meeus, G., additional, Reffert, S., additional, Kenworthy, M., additional, Meyer, M. R., additional, Bonnefoy, M., additional, Bonavita, M., additional, Mesa, D., additional, Samland, M., additional, Desidera, S., additional, D’Orazi, V., additional, Engler, N., additional, Alecian, E., additional, Miglio, A., additional, Henning, T., additional, Quanz, S. P., additional, Mayer, L., additional, Flasseur, O., additional, and Marleau, G.-D., additional

Published

2022

4. The SPHERE Infrared Survey for Exoplanets (SHINE): II. Observations, Data Reduction and Analysis, Detection Performances, and Initial Results

Author

Langlois, M., Gratton, R., Lagrange, A. -M., Delorme, P., Boccaletti, A., Bonnefoy, M., Maire, A. -L., Mesa, D., Chauvin, G., Desidera, S., Vigan, A., Cheetham, A., Hagelberg, J., Feldt, M., Meyer, M., Rubini, P., Le, Coroller, H., Cantalloube, F., Biller, B., Bonavita, M., Bhowmik, T., Brandner, W., Daemgen, S., D'Orazi, V., Flasseur, O., Fontanive, C., Galicher, R., Girard, J., Janin-Potiron, P., Janson, M., Keppler, M., Kopytova, T., Lagadec, E., Lannier, J., Lazzoni, C., Ligi, R., Meunier, N., Perreti, A., Perrot, C., Rodet, L., Romero, C., Rouan, D., Samland, M., Salter, G., Sissa, E., Schmidt, T., Zurlo, A., Mouillet, D., Denis, L., Thiébaut, E., Milli, J., Wahhaj, Z., Beuzit, J. -L., Dominik, C., Henning, T., Ménard, F., Müller, A., Schmid, H. M., Turatto, M., Udry, S., Abe, L., Antichi, J., Allard, F., Baruffolo, A., Baudoz, P., Baudrand, J., Bazzon, A., Blanchard, P., Carbillet, M., Carle, M., Cascone, E., Charton, J., Claudi, R., Costille, A., De Caprio, V., Delboulbé, A., Dohlen, K., Fantinel, D., Feautrier, P., Fusco, T., Gigan, P., Giro, E., Gisler, D., Gluck, L., Gry, C., Hubin, N., Hugot, E., Jaquet, M., Kasper, M., Le Mignant, D., Llored, M., Madec, F., Magnard, Y., Martinez, P., Maurel, D., Messina, S., Möller-Nilsson, O., Mugnier, L., Moulin, T., Origné, A., Pavlov, A., Perret, D., Petit, C., Pragt, J., Puget, P., Rabou, P., Ramos, J., Rigal, F., Rochat, S., Roelfsema, R., Rousset, G., Roux, A., Salasnich, B., Sauvage, J. -F., Sevin, A., Soenke, C., Stadler, E., Suarez, M., Weber, L., Wildi, F., and Rickman, E.

Subjects

STATISTICAL [METHODS], IMAGING TECHNIQUES, INFRARED DEVICES, FORMATION [PLANETS AND SATELLITES], DETECTION PERFORMANCE, IMAGE PROCESSING [TECHNIQUES], EXTREMELY LARGE TELESCOPES, COLOR MAGNITUDE DIAGRAMS, ANALYSIS STRATEGIES, FORMATION AND EVOLUTIONS, SEARCH ENGINES, OBSERVATIONAL [METHODS], STATISTICAL PROPERTIES, HIGH ANGULAR RESOLUTION [INSTRUMENTATION], DETECTION [PLANETS AND SATELLITES], ORBITS, LARGE FIELD OF VIEWS, POPULATION STATISTICS, SURVEYS, INTEGRAL FIELD SPECTROGRAPH, STARS, EXTRASOLAR PLANETS

Abstract

Context. In recent decades, direct imaging has confirmed the existence of substellar companions (exoplanets or brown dwarfs) on wide orbits (>10 au) around their host stars. In striving to understand their formation and evolution mechanisms, in 2015 we initiated the SPHERE infrared survey for exoplanets (SHINE), a systematic direct imaging survey of young, nearby stars that is targeted at exploring their demographics. Aims. We aim to detect and characterize the population of giant planets and brown dwarfs beyond the snow line around young, nearby stars. Combined with the survey completeness, our observations offer the opportunity to constrain the statistical properties (occurrence, mass and orbital distributions, dependency on the stellar mass) of these young giant planets. Methods. In this study, we present the observing and data analysis strategy, the ranking process of the detected candidates, and the survey performances for a subsample of 150 stars that are representative of the full SHINE sample. Observations were conducted in a homogeneous way between February 2015 and February 2017 with the dedicated ground-based VLT/SPHERE instrument equipped with the IFS integral field spectrograph and the IRDIS dual-band imager, covering a spectral range between 0.9 and 2.3 μm. We used coronographic, angular, and spectral differential imaging techniques to achieve the best detection performances for this study, down to the planetary mass regime. Results. We processed, in a uniform manner, more than 300 SHINE observations and datasets to assess the survey typical sensitivity as a function of the host star and of the observing conditions. The median detection performance reached 5σ-contrasts of 13 mag at 200 mas and 14.2 mag at 800 mas with the IFS (YJ and YJH bands), and of 11.8 mag at 200 mas, 13.1 mag at 800 mas, and 15.8 mag at 3 as with IRDIS in H band, delivering one of the deepest sensitivity surveys thus far for young, nearby stars. A total of sixteen substellar companions were imaged in this first part of SHINE: seven brown dwarf companions and ten planetary-mass companions.These include two new discoveries, HIP 65426 b and HIP 64892 B, but not the planets around PDS70 that had not been originally selected for the SHINE core sample. A total of 1483 candidates were detected, mainly in the large field of view that characterizes IRDIS. The color-magnitude diagrams, low-resolution spectrum (when available with IFS), and follow-up observations enabled us to identify the nature (background contaminant or comoving companion) of about 86% of our subsample. The remaining cases are often connected to crowded-field follow-up observations that were missing. Finally, even though SHINE was not initially designed for disk searches, we imaged twelve circumstellar disks, including three new detections around the HIP 73145, HIP 86598, and HD 106906 systems. Conclusions. Nowadays, direct imaging provides a unique opportunity to probe the outer part of exoplanetary systems beyond 10 au to explore planetary architectures, as highlighted by the discoveries of: one new exoplanet, one new brown dwarf companion, and three new debris disks during this early phase of SHINE. It also offers the opportunity to explore and revisit the physical and orbital properties of these young, giant planets and brown dwarf companions (relative position, photometry, and low-resolution spectrum in near-infrared, predicted masses, and contrast in order to search for additional companions). Finally, these results highlight the importance of finalizing the SHINE systematic observation of about 500 young, nearby stars for a full exploration of their outer part to explore the demographics of young giant planets beyond 10 au and to identify the most interesting systems for the next generation of high-contrast imagers on very large and extremely large telescopes. © M. Langlois et al. 2021. 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 Zürich (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 CommissionSixth 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). This paper is based on observations collected at the European Southern Observatory under ESO programmes 198.C-0209, 097.C-0865, 095.C-0298, 095.C-0309,096.C-0241. This work has made use of the SPHERE Data Centre, jointly operated by OSUG/IPAG (Grenoble), PYTHEAS/LAM/CeSAM (Marseille), OCA/Lagrange (Nice), Observatoire de Paris/LESIA (Paris), and Observatoire de Lyon (OSUL/CRAL). This work is supported by the French National Research Agency in the framework of the Investissements d’Avenir program (ANR-15-IDEX-02), through the funding of the “Origin of Life” project of the Univ. Grenoble-Alpes. This work is jointly supported by the French National Programms (PNP and PNPS) and by the Action Spécifique Haute Résolution Angulaire (ASHRA) of CNRS/INSU co-funded by CNES. We also thank the anonymous referee for her/his careful reading of the manuscript as well as her/his insightful comments and suggestions. AV acknowledges funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement No. 757561). A.-M.L. acknowledges funding from French National Research Agency (GIPSE project). C.P. acknowledges financial support from Fondecyt (grant 3190691) and financial support from the ICM (Iniciativa Científica Milenio) via the Núcleo Milenio de Formación Planetaria grant, from the Universidad de Valparaíso. T.H. acknowledges support from the European Research Council under the Horizon 2020 Framework Program via the ERC Advanced Grant Origins 832428.

Published

2021

5. The SPHERE infrared survey for exoplanets (SHINE)

Author

Langlois, M., primary, Gratton, R., additional, Lagrange, A.-M., additional, Delorme, P., additional, Boccaletti, A., additional, Bonnefoy, M., additional, Maire, A.-L., additional, Mesa, D., additional, Chauvin, G., additional, Desidera, S., additional, Vigan, A., additional, Cheetham, A., additional, Hagelberg, J., additional, Feldt, M., additional, Meyer, M., additional, Rubini, P., additional, Le Coroller, H., additional, Cantalloube, F., additional, Biller, B., additional, Bonavita, M., additional, Bhowmik, T., additional, Brandner, W., additional, Daemgen, S., additional, D’Orazi, V., additional, Flasseur, O., additional, Fontanive, C., additional, Galicher, R., additional, Girard, J., additional, Janin-Potiron, P., additional, Janson, M., additional, Keppler, M., additional, Kopytova, T., additional, Lagadec, E., additional, Lannier, J., additional, Lazzoni, C., additional, Ligi, R., additional, Meunier, N., additional, Perreti, A., additional, Perrot, C., additional, Rodet, L., additional, Romero, C., additional, Rouan, D., additional, Samland, M., additional, Salter, G., additional, Sissa, E., additional, Schmidt, T., additional, Zurlo, A., additional, Mouillet, D., additional, Denis, L., additional, Thiébaut, E., additional, Milli, J., additional, Wahhaj, Z., additional, Beuzit, J.-L., additional, Dominik, C., additional, Henning, Th., additional, Ménard, F., additional, Müller, A., additional, Schmid, H. M., additional, Turatto, M., additional, Udry, S., additional, Abe, L., additional, Antichi, J., additional, Allard, F., additional, Baruffolo, A., additional, Baudoz, P., additional, Baudrand, J., additional, Bazzon, A., additional, Blanchard, P., additional, Carbillet, M., additional, Carle, M., additional, Cascone, E., additional, Charton, J., additional, Claudi, R., additional, Costille, A., additional, De Caprio, V., additional, Delboulbé, A., additional, Dohlen, K., additional, Fantinel, D., additional, Feautrier, P., additional, Fusco, T., additional, Gigan, P., additional, Giro, E., additional, Gisler, D., additional, Gluck, L., additional, Gry, C., additional, Hubin, N., additional, Hugot, E., additional, Jaquet, M., additional, Kasper, M., additional, Le Mignant, D., additional, Llored, M., additional, Madec, F., additional, Magnard, Y., additional, Martinez, P., additional, Maurel, D., additional, Messina, S., additional, Möller-Nilsson, O., additional, Mugnier, L., additional, Moulin, T., additional, Origné, A., additional, Pavlov, A., additional, Perret, D., additional, Petit, C., additional, Pragt, J., additional, Puget, P., additional, Rabou, P., additional, Ramos, J., additional, Rigal, F., additional, Rochat, S., additional, Roelfsema, R., additional, Rousset, G., additional, Roux, A., additional, Salasnich, B., additional, Sauvage, J.-F., additional, Sevin, A., additional, Soenke, C., additional, Stadler, E., additional, Suarez, M., additional, Weber, L., additional, Wildi, F., additional, and Rickman, E., additional

Published

2021

6. VLT/SPHERE exploration of the young multiplanetary system PDS70

Author

Mesa, D., primary, Keppler, M., additional, Cantalloube, F., additional, Rodet, L., additional, Charnay, B., additional, Gratton, R., additional, Langlois, M., additional, Boccaletti, A., additional, Bonnefoy, M., additional, Vigan, A., additional, Flasseur, O., additional, Bae, J., additional, Benisty, M., additional, Chauvin, G., additional, de Boer, J., additional, Desidera, S., additional, Henning, T., additional, Lagrange, A.-M., additional, Meyer, M., additional, Milli, J., additional, Müller, A., additional, Pairet, B., additional, Zurlo, A., additional, Antoniucci, S., additional, Baudino, J.-L., additional, Brown Sevilla, S., additional, Cascone, E., additional, Cheetham, A., additional, Claudi, R. U., additional, Delorme, P., additional, D’Orazi, V., additional, Feldt, M., additional, Hagelberg, J., additional, Janson, M., additional, Kral, Q., additional, Lagadec, E., additional, Lazzoni, C., additional, Ligi, R., additional, Maire, A.-L., additional, Martinez, P., additional, Menard, F., additional, Meunier, N., additional, Perrot, C., additional, Petrus, S., additional, Pinte, C., additional, Rickman, E. L., additional, Rochat, S., additional, Rouan, D., additional, Samland, M., additional, Sauvage, J.-F., additional, Schmidt, T., additional, Udry, S., additional, Weber, L., additional, and Wildi, F., additional

Published

2019

7. Unveiling the β Pictoris system, coupling high contrast imaging, interferometric, and radial velocity data.

Author

Lagrange, A. M., Rubini, P., Nowak, M., Lacour, S., Grandjean, A., Boccaletti, A., Langlois, M., Delorme, P., Gratton, R., Wang, J., Flasseur, O., Galicher, R., Kral, Q., Meunier, N., Beust, H., Babusiaux, C., Le Coroller, H., Thebault, P., Kervella, P., and Zurlo, A.

Subjects

MONTE Carlo method, ORIGIN of planets, PLANETARY systems, PLANETARY orbits, GAS giants, VELOCITY, ASTROMETRY, INNER planets

Abstract

Context. The nearby and young β Pictoris system hosts a well resolved disk, a directly imaged massive giant planet orbiting at ≃9 au, as well as an inner planet orbiting at ≃2.7 au, which was recently detected through radial velocity (RV). As such, it offers several unique opportunities for detailed studies of planetary system formation and early evolution. Aims. We aim to further constrain the orbital and physical properties of β Pictoris b and c using a combination of high contrast imaging, long base-line interferometry, and RV data. We also predict the closest approaches or the transit times of both planets, and we constrain the presence of additional planets in the system. Methods. We obtained six additional epochs of SPHERE data, six additional epochs of GRAVITY data, and five additional epochs of RV data. We combined these various types of data in a single Markov-chain Monte Carlo analysis to constrain the orbital parameters and masses of the two planets simultaneously. The analysis takes into account the gravitational influence of both planets on the star and hence their relative astrometry. Secondly, we used the RV and high contrast imaging data to derive the probabilities of presence of additional planets throughout the disk, and we tested the impact of absolute astrometry. Results. The orbital properties of both planets are constrained with a semi-major axis of 9.8 ± 0.4 au and 2.7 ± 0.02 au for b and c, respectively, and eccentricities of 0.09 ± 0.1 and 0.27 ± 0.07, assuming the HIPPARCOS distance. We note that despite these low fitting error bars, the eccentricity of β Pictoris c might still be over-estimated. If no prior is provided on the mass of β Pictoris b, we obtain a very low value that is inconsistent with what is derived from brightness-mass models. When we set an evolutionary model motivated prior to the mass of β Pictoris b, we find a solution in the 10–11 MJup range. Conversely, β Pictoris c's mass is well constrained, at 7.8 ± 0.4 MJup, assuming both planets are on coplanar orbits. These values depend on the assumptions on the distance of the β Pictoris system. The absolute astrometry HIPPARCOS-Gaia data are consistent with the solutions presented here at the 2σ level, but these solutions are fully driven by the relative astrometry plus RV data. Finally, we derive unprecedented limits on the presence of additional planets in the disk. We can now exclude the presence of planets that are more massive than about 2.5 MJup closer than 3 au, and more massive than 3.5 MJup between 3 and 7.5 au. Beyond 7.5 au, we exclude the presence of planets that are more massive than 1–2 MJup. Conclusions. Combining relative astrometry and RVs allows one to precisely constrain the orbital parameters of both planets and to give lower limits to potential additional planets throughout the disk. The mass of β Pictoris c is also well constrained, while additional RV data with appropriate observing strategies are required to properly constrain the mass of β Pictoris b. [ABSTRACT FROM AUTHOR]

Published

2020