THE 8 μm PHASE VARIATION OF THE HOT SATURN HD 149026b

Knutson, Heather A.; Charbonneau, David; Cowan, Nicolas B.; Fortney, Jonathan J.; Showman, Adam P.; Agol, Eric; Henry, Gregory W.

doi:10.1088/0004-637x/703/1/769

Cited by 127 publications

(125 citation statements)

References 71 publications

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“…Over the past few years, it has become possible to constrain the magnitude of wind advection in the atmosphere of a few hot giant exoplanets, by measuring their infrared phase curves (e.g., Harrington et al 2006;Cowan et al 2007;Knutson et al 2007Knutson et al , 2009aKnutson et al , 2009bCrossfield et al 2010). The standard interpretation that has been given to an infrared peak emission that is offset from the planet's orbital phase is that heat is advected away from the dayside by eastward equatorial winds at the planet's thermal photosphere (e.g., Showman et al 2008Showman et al , 2009Showman et al , 2010Dobbs-Dixon et al 2010;Heng et al 2011;Showman & Polvani 2011).…”

Section: Observational Signaturesmentioning

confidence: 99%

Magnetic Scaling Laws for the Atmospheres of Hot Giant Exoplanets

Menou

2012

ApJ

122

148

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We present scaling laws for advection, radiation, magnetic drag, and ohmic dissipation in the atmospheres of hot giant exoplanets. In the limit of weak thermal ionization, ohmic dissipation increases with the planetary equilibrium temperature (T eq 1000 K) faster than the insolation power does, eventually reaching values 1% of the insolation power, which may be sufficient to inflate the radii of hot Jupiters. At higher T eq values still magnetic drag rapidly brakes the atmospheric winds, which reduces the associated ohmic dissipation power. For example, for a planetary field strength B = 10 G, the fiducial scaling laws indicate that ohmic dissipation exceeds 1% of the insolation power over the equilibrium temperature range T eq ∼ 1300-2000 K, with a peak contribution at T eq ∼ 1600 K. Evidence for magnetically dragged winds at the planetary thermal photosphere could emerge in the form of reduced longitudinal offsets for the dayside infrared hotspot. This suggests the possibility of an anticorrelation between the amount of hotspot offset and the degree of radius inflation, linking the atmospheric and interior properties of hot giant exoplanets in an observationally testable way. While providing a useful framework to explore the magnetic scenario, the scaling laws also reveal strong parameter dependencies, in particular with respect to the unknown planetary magnetic field strength.

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Section: Observational Signaturesmentioning

confidence: 99%

Magnetic Scaling Laws for the Atmospheres of Hot Giant Exoplanets

Menou

2012

ApJ

122

148

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“…A DE-MCMC analysis with a number of chains equal to twice the number of free parameters was then carried out. After removing the burn-in steps, as suggested by Knutson et al (2009), and achieving convergence and a good mixing of the chains according to Ford (2006), the medians of the posterior distributions and their 34.13% intervals were evaluated and were taken as the final parameters and associated 1σ uncertainties. Mass, radius, and age of the host star were determined by comparing the YonseiYale evolutionary tracks (Demarque et al 2004) with the stellar effective temperature, metallicity, and density as derived from a/R and Kepler's third law (see, e.g., Sozzetti et al 2007;Torres et al 2012).…”

Section: Data Analysis and System Parametersmentioning

confidence: 99%

Characterization of the planetary system Kepler-101 with HARPS-N

Bonomo

Sozzetti

Lovis

et al. 2014

A&A

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We characterize the planetary system Kepler-101 by performing a combined differential evolution Markov chain Monte Carlo analysis of Kepler data and forty radial velocities obtained with the HARPS-N spectrograph. This system was previously validated and is composed of a hot super-Neptune, Kepler-101b, and an Earth-sized planet, Kepler-101c. These two planets orbit the slightly evolved and metal-rich G-type star in 3.49 and 6.03 days, respectively. With mass M p = 51.1 +5.1 −4.7 M ⊕ , radius R p = 5.77 +0.85 −0.79 R ⊕ , and density ρ p = 1.45 +0.83 −0.48 g cm −3 , Kepler-101b is the first fully characterized super-Neptune, and its density suggests that heavy elements make up a significant fraction of its interior; more than 60% of its total mass. Kepler-101c has a radius of 1.25 +0.19 −0.17 R ⊕ , which implies the absence of any H/He envelope, but its mass could not be determined because of the relative faintness of the parent star for highly precise radial-velocity measurements (K p = 13.8) and the limited number of radial velocities. The 1σ upper limit, M p < 3.8 M ⊕ , excludes a pure iron composition with a probability of 68.3%. The architecture of the planetary system Kepler-101 − containing a close-in giant planet and an outer Earth-sized planet with a period ratio slightly larger than the 3:2 resonance − is certainly of interest for scenarios of planet formation and evolution. This system does not follow the previously reported trend that the larger planet has the longer period in the majority of Kepler systems of planet pairs with at least one Neptune-sized or larger planet.

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“…The detection of the exoplanet emission spectra was also possible through high-resolution spectroscopy (Brogi et al 2012;Rodler et al 2012;de Kok et al 2014). The measurement of phase variations relies on the detection of the flux variation along the planet's orbit as it alternately presents its day and night hemisphere to us (e.g., Knutson et al 2009;Kane et al 2011). These techniques represent the current front line of exoplanet characterization and are limited only by flux measurement precision that they impose as a result of the low planet-star flux ratio (e.g., in the most favorable cases, for a Jupiter sized planet with a 3 day period orbit F Planet /F Star ≈ 10 −4 in the visible and F Planet /F Star ≈ 10 −3 in the IR).…”

Section: Introductionmentioning

confidence: 99%

Evidence for a spectroscopic direct detection of reflected light from 51 Pegasi b

Martins

Santos

Figueira

et al. 2015

A&A

133

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Context. The detection of reflected light from an exoplanet is a difficult technical challenge at optical wavelengths. Even though this signal is expected to replicate the stellar signal, not only is it several orders of magnitude fainter, but it is also hidden among the stellar noise. Aims. We apply a variant of the cross-correlation technique to HARPS observations of 51 Peg to detect the reflected signal from planet 51 Peg b. Methods. Our method makes use of the cross-correlation function (CCF) of a binary mask with high-resolution spectra to amplify the minute planetary signal that is present in the spectra by a factor proportional to the number of spectral lines when performing the cross correlation. The resulting cross-correlation functions are then normalized by a stellar template to remove the stellar signal. Carefully selected sections of the resulting normalized CCFs are stacked to increase the planetary signal further. The recovered signal allows probing several of the planetary properties, including its real mass and albedo. Results. We detect evidence for the reflected signal from planet 51 Peg b at a significance of 3σ noise . The detection of the signal permits us to infer a real mass of 0.46 +0.06 −0.01 M Jup (assuming a stellar mass of 1.04 M Sun ) for the planet and an orbital inclination of 80 +10 −19 degrees. The analysis of the data also allows us to infer a tentative value for the (radius-dependent) geometric albedo of the planet. The results suggest that 51Peg b may be an inflated hot Jupiter with a high albedo (e.g., an albedo of 0.5 yields a radius of 1.9 ± 0.3 R Jup for a signal amplitude of 6.0 ± 0.4 × 10 −5 ). Conclusions. We confirm that the method we perfected can be used to retrieve an exoplanet's reflected signal, even with current observing facilities. The advent of next generation of instruments (e.g. VLT-ESO/ESPRESSO) and observing facilities (e.g. a new generation of ELT telescopes) will yield new opportunities for this type of technique to probe deeper into exoplanets and their atmospheres.

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THE 8 μm PHASE VARIATION OF THE HOT SATURN HD 149026b

Cited by 127 publications

References 71 publications

Magnetic Scaling Laws for the Atmospheres of Hot Giant Exoplanets

Magnetic Scaling Laws for the Atmospheres of Hot Giant Exoplanets

Characterization of the planetary system Kepler-101 with HARPS-N

Evidence for a spectroscopic direct detection of reflected light from 51 Pegasi b

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