HD 5388 b is a 69 <i>M</i><sub>Jup</sub>companion instead of a planet

Sahlmann, J.; Lovis, C.; Queloz, D.; Ségransan, D.

doi:10.1051/0004-6361/201116533

Cited by 31 publications

(21 citation statements)

References 23 publications

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“…Many other dynamical measurements have targeted companions to M-stars, thus helping to circumvent issues with contrast (Zapatero Osorio et al 2004;Ireland et al 2008;Dupuy et al 2009b;Konopacky et al 2010), but M-star metallicities are notoriously difficult to determine (Johnson & Apps 2009). Low-mass companions to solar-type stars have also been studied using Doppler measurements in combination with Hubble Space Telescope astrometry (Benedict et al 2010) and Hipparcos intermediate astrometry (Sahlmann et al 2011), but indirect observations preclude a comparison between spectral models and dynamical mass measurements by definition. One comparable system, HD130948BC, consists of a double brown dwarf orbiting a G2V primary.…”

Section: Summary and Discussionmentioning

confidence: 99%

The Dynamical Mass and Three-Dimensional Orbit of Hr7672b: A Benchmark Brown Dwarf With High Eccentricity

Crepp

Johnson

Fischer

et al. 2012

ApJ

103

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The companion to the G0V star HR7672 directly imaged by Liu et al. has moved measurably along its orbit since the discovery epoch, making it possible to determine its dynamical properties. Originally targeted with adaptive optics because it showed a long-term radial velocity (RV) acceleration (trend), we have monitored this star with precise Doppler measurements and have now established a 24 year time baseline. The RV variations show significant curvature (change in the acceleration) including an inflection point. We have also obtained a recent image of HR7672B with NIRC2 at Keck. The astrometry also shows curvature. In this paper, we use jointly fitted Doppler and astrometric models to calculate the three-dimensional orbit and dynamical mass of the companion. The mass of the host star is determined using a direct radius measurement from CHARA interferometry in combination with high-resolution spectroscopic modeling. We find that HR7672B has a highly eccentric, e = 0.50 +0.01 −0.01 , near edge-on, i = 97.3 +0.4 −0.5 deg, orbit with semimajor axis, a = 18.3 +0.4 −0.5 AU. The mass of the companion is m = 68.7 +2.4 −3.1 M J . HR7672B thus resides near the substellar boundary, just below the hydrogen-fusing limit. These measurements of the companion mass are independent of its brightness and spectrum and establish HR7672B as a rare and precious "benchmark" brown dwarf with a well-determined mass, age, and metallicity essential for testing theoretical evolutionary models and synthetic spectral models. Indeed, we find that such models under-predict its luminosity by a factor of ≈2. HR 7672B is presently the only L, T, or Y dwarf known to produce an RV trend around a solar-type star.

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Section: Summary and Discussionmentioning

confidence: 99%

The Dynamical Mass and Three-Dimensional Orbit of Hr7672b: A Benchmark Brown Dwarf With High Eccentricity

Crepp

Johnson

Fischer

et al. 2012

ApJ

103

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“…The deduced planet masses are therefore uncertain due to the unknown orbital inclination, named the sin i ambiguity. Astrometric measurements of the stellar barycentric orbit can determine the orbit's inclination accurately and remove the mass ambiguity, [5][6][7][8] thereby leading to a better determination of the planet mass distribution. Because 5 of the 7 parameters describing the orbit are known from RV, the astrometric orbit detection is eased.…”

Section: Accurate Masses Of Known Exoplanetsmentioning

confidence: 99%

Enabling science with Gaia observations of naked-eye stars

et al. 2016

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ESA's Gaia space astrometry mission is performing an all-sky survey of stellar objects. At the beginning of the nominal mission in July 2014, an operation scheme was adopted that enabled Gaia to routinely acquire observations of all stars brighter than the original limit of G∼6, i.e. the naked-eye stars. Here, we describe the current status and extent of those observations and their on-ground processing. We present an overview of the data products generated for G<6 stars and the potential scientific applications. Finally, we discuss how the Gaia survey could be enhanced by further exploiting the techniques we developed.

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“…Several techniques have been developed to measure the spin-orbit angle: spectroscopically, via the RossiterMcLaughlin effect (Holt 1893;Rossiter 1924;McLaughlin 1924;Queloz et al 2000;Gaudi & Winn 2007;Boué et al 2013) and the Doppler shadow ; statistically (Schlaufman 2010); photometrically thanks to gravity darkening (Szabó et al 2011) or through spot-crossing events (Nutzman et al 2011;Sanchis-Ojeda et al 2012); astrometrically (Sahlmann et al 2011); using asteroseismologic mode splitting (Chaplin et al 2013); or interferometrically (Le Bouquin et al 2009). Searching for transits on non-eclipsing binaries would become another way to detect inclined orbits by spatially resolving the misalignment.…”

Section: Towards the Detection Of Planets Transiting Non-eclipsing Bimentioning

confidence: 99%

Planets transiting non-eclipsing binaries

Martin

Triaud

2014

A&A

106

141

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The majority of binary stars do not eclipse. Current searches for transiting circumbinary planets concentrate on eclipsing binaries, and are therefore restricted to a small fraction of potential hosts. We investigate the concept of finding planets transiting non-eclipsing binaries, whose geometry would require mutually inclined planes. Using an N-body code we explore how the number and sequence of transits vary as functions of observing time and orbital parameters. The concept is then generalised thanks to a suite of simulated circumbinary systems. Binaries are constructed from radial-velocity surveys of the solar neighbourhood. They are then populated with orbiting gas giants, drawn from a range of distributions. The binary population is shown to be compatible with the Kepler eclipsing binary catalogue, indicating that the properties of binaries may be as universal as the initial mass function. These synthetic systems produce transiting circumbinary planets occurring on both eclipsing and non-eclipsing binaries. Simulated planets transiting eclipsing binaries are compared with published Kepler detections. We find 1) that planets transiting non-eclipsing binaries are probably present in the Kepler data; 2) that observational biases alone cannot account for the observed over-density of circumbinary planets near the stability limit, which implies a physical pile-up; and 3) that the distributions of gas giants orbiting single and binary stars are likely different. Estimating the frequency of circumbinary planets is degenerate with the spread in mutual inclination. Only a minimum occurrence rate can be produced, which we find to be compatible with 9%. Searching for inclined circumbinary planets may significantly increase the population of known objects and will test our conclusions. Their presence, or absence, will reveal the true occurrence rate and help develop circumbinary planet formation theories.

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HD 5388 b is a 69 M_Jupcompanion instead of a planet

Cited by 31 publications

References 23 publications

The Dynamical Mass and Three-Dimensional Orbit of Hr7672b: A Benchmark Brown Dwarf With High Eccentricity

The Dynamical Mass and Three-Dimensional Orbit of Hr7672b: A Benchmark Brown Dwarf With High Eccentricity

Enabling science with Gaia observations of naked-eye stars

Planets transiting non-eclipsing binaries

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HD 5388 b is a 69 MJupcompanion instead of a planet

Cited by 31 publications

References 23 publications

The Dynamical Mass and Three-Dimensional Orbit of Hr7672b: A Benchmark Brown Dwarf With High Eccentricity

The Dynamical Mass and Three-Dimensional Orbit of Hr7672b: A Benchmark Brown Dwarf With High Eccentricity

Enabling science with Gaia observations of naked-eye stars

Planets transiting non-eclipsing binaries

Contact Info

Product

Resources

About

HD 5388 b is a 69 M_Jupcompanion instead of a planet