Your search keyword '"Amaury H. M. J. Triaud"' showing total 4 results

1. Stellar Parameters for Trappist-1.

Author

Valérie Van Grootel, Catarina S. Fernandes, Michael Gillon, Emmanuel Jehin, Jean Manfroid, Richard Scuflaire, Adam J. Burgasser, Khalid Barkaoui, Zouhair Benkhaldoun, Artem Burdanov, Laetitia Delrez, Brice-Olivier Demory, Julien de Wit, Didier Queloz, and Amaury H. M. J. Triaud

Subjects

STELLAR mass, TELESCOPES, STELLAR populations, ATOMIC mass, STELLAR luminosity function

Abstract

TRAPPIST-1 is an ultracool dwarf star transited by seven Earth-sized planets, for which thorough characterization of atmospheric properties, surface conditions encompassing habitability, and internal compositions is possible with current and next-generation telescopes. Accurate modeling of the star is essential to achieve this goal. We aim to obtain updated stellar parameters for TRAPPIST-1 based on new measurements and evolutionary models, compared to those used in discovery studies. We present a new measurement for the parallax of TRAPPIST-1, 82.4 ± 0.8 mas, based on 188 epochs of observations with the TRAPPIST and Liverpool Telescopes from 2013 to 2016. This revised parallax yields an updated luminosity of , which is very close to the previous estimate but almost two times more precise. We next present an updated estimate for TRAPPIST-1 stellar mass, based on two approaches: mass from stellar evolution modeling, and empirical mass derived from dynamical masses of equivalently classified ultracool dwarfs in astrometric binaries. We combine them using a Monte-Carlo approach to derive a semi-empirical estimate for the mass of TRAPPIST-1. We also derive estimate for the radius by combining this mass with stellar density inferred from transits, as well as an estimate for the effective temperature from our revised luminosity and radius. Our final results are , , and 2516 ± 41 K. Considering the degree to which the TRAPPIST-1 system will be scrutinized in coming years, these revised and more precise stellar parameters should be considered when assessing the properties of TRAPPIST-1 planets. [ABSTRACT FROM AUTHOR]

Published

2018

2. WARM JUPITERS ARE LESS LONELY THAN HOT JUPITERS: CLOSE NEIGHBORS.

Author

Chelsea Huang, Yanqin Wu, and Amaury H. M. J. Triaud

Subjects

JUPITER (Planet), STELLAR density (Stellar population), ACCRETION (Astrophysics), GAS giants, PLANETARY mass, ORIGIN of planets

Abstract

Exploiting the Kepler transit data, we uncover a dramatic distinction in the prevalence of sub-Jovian companions between systems that contain hot Jupiters (HJs) (periods inward of 10 days) and those that host warm Jupiters (WJs) (periods between 10 and 200 days). HJs, with the singular exception of WASP-47b, do not have any detectable inner or outer planetary companions (with periods inward of 50 days and sizes down to 2 REarth). Restricting ourselves to inner companions, our limits reach down to 1 REarth. In stark contrast, half of the WJs are closely flanked by small companions. Statistically, the companion fractions for hot and WJs are mutually exclusive, particularly in regard to inner companions. The high companion fraction of WJs also yields clues to their formation. The WJs that have close-by siblings should have low orbital eccentricities and low mutual inclinations. The orbital configurations of these systems are reminiscent of those of the low-mass close-in planetary systems abundantly discovered by the Kepler mission. This, and other arguments, lead us to propose that these WJs are formed in situ. There are indications that there may be a second population of WJs with different characteristics. In this picture, WASP-47b could be regarded as the extending tail of the in situ WJs into the HJ region and does not represent the generic formation route for HJs. [ABSTRACT FROM AUTHOR]

Published

2016

3. TESTS OF THE PLANETARY HYPOTHESIS FOR PTFO 8-8695b.

Author

Liang Yu, Joshua N. Winn, Saul Rappaport, Fei Dai, Amaury H. M. J. Triaud, Philip Muirhead, Michaël Gillon, Laetitia Delrez, Emmanuel Jehin, Monika Lendl, Simon Albrecht, Allyson Bieryla, Matthew J. Holman, Benjamin T. Montet, Lynne Hillenbrand, Andrew W. Howard, Chelsea X. Huang, Howard Isaacson, and Roberto Sanchis-Ojeda

Subjects

T Tauri stars, PLANETARY orbits, LIGHT curves, TIME series analysis, OCCULTATIONS (Astronomy)

Abstract

The T Tauri star PTFO 8-8695 exhibits periodic fading events that have been interpreted as the transits of a giant planet on a precessing orbit. Here we present three tests of the planet hypothesis. First, we sought evidence for the secular changes in light-curve morphology that are predicted to be a consequence of orbital precession. We observed 28 fading events spread over several years and did not see the expected changes. Instead, we found that the fading events are not strictly periodic. Second, we attempted to detect the planet's radiation, based on infrared observations spanning the predicted times of occultations. We ruled out a signal of the expected amplitude. Third, we attempted to detect the Rossiter–McLaughlin effect by performing high-resolution spectroscopy throughout a fading event. No effect was seen at the expected level, ruling out most (but not all) possible orientations for the hypothetical planetary orbit. Our spectroscopy also revealed strong, time-variable, high-velocity Hα and Ca H & K emission features. All these observations cast doubt on the planetary hypothesis, and suggest instead that the fading events represent starspots, eclipses by circumstellar dust, or occultations of an accretion hotspot. [ABSTRACT FROM AUTHOR]

Published

2015

4. SPITZER SECONDARY ECLIPSE OBSERVATIONS OF FIVE COOL GAS GIANT PLANETS AND EMPIRICAL TRENDS IN COOL PLANET EMISSION SPECTRA.

Author

Joshua A. Kammer, Heather A. Knutson, Michael R. Line, Jonathan J. Fortney, Drake Deming, Adam Burrows, Nicolas B. Cowan, Amaury H. M. J. Triaud, Eric Agol, Jean-Michel Desert, Benjamin J. Fulton, Andrew W. Howard, Gregory P. Laughlin, Nikole K. Lewis, Caroline V. Morley, Julianne I. Moses, Adam P. Showman, and Kamen O. Todorov

Subjects

PLANETARY observations, ECLIPSES, COLD gases, TRENDS, EMISSION spectroscopy, ATMOSPHERIC models, JUPITER (Planet)

Abstract

In this work we present Spitzer 3.6 and 4.5 μm secondary eclipse observations of five new cool ( K) transiting gas giant planets: HAT-P-19b, WASP-6b, WASP-10b, WASP-39b, and WASP-67b. We compare our measured eclipse depths to the predictions of a suite of atmosphere models and to eclipse depths for planets with previously published observations in order to constrain the temperature- and mass-dependent properties of gas giant planet atmospheres. We find that the dayside emission spectra of planets less massive than Jupiter require models with efficient circulation of energy to the night side and/or increased albedos, while those with masses greater than that of Jupiter are consistently best-matched by models with inefficient circulation and low albedos. At these relatively low temperatures we expect the atmospheric CH4/CO ratio to vary as a function of metallicity, and we therefore use our observations of these planets to constrain their atmospheric metallicities. We find that the most massive planets have dayside emission spectra that are best-matched by solar metallicity atmosphere models, but we are not able to place strong constraints on metallicities of the smaller planets in our sample. Interestingly, we find that the ratio of the 3.6 and 4.5 μm brightness temperatures for these cool transiting planets is independent of planet temperature, and instead exhibits a tentative correlation with planet mass. If this trend can be confirmed, it would suggest that the shape of these planets’ emission spectra depends primarily on their masses, consistent with the hypothesis that lower-mass planets are more likely to have metal-rich atmospheres. [ABSTRACT FROM AUTHOR]

Published

2015