Raissa Estrela scite author profile

We report the detection of an atmosphere on a rocky exoplanet, GJ 1132 b, which is similar to Earth in terms of size and density. The atmospheric transmission spectrum was detected using Hubble WFC3 measurements and shows spectral signatures of aerosol scattering, HCN, and CH4 in a low mean molecular weight atmosphere. We model the atmospheric loss process and conclude that GJ 1132 b likely lost the original H/He envelope, suggesting that the atmosphere that we detect has been reestablished. We explore the possibility of H2 mantle degassing, previously identified as a possibility for this planet by theoretical studies, and find that outgassing from ultra-reduced magma could produce the observed atmosphere. In this way we use the observed exoplanet transmission spectrum to gain insights into magma composition for a terrestrial planet. The detection of an atmosphere on this rocky planet raises the possibility that the numerous powerfully irradiated super-Earth planets, believed to be the evaporated cores of sub-Neptunes, may, under favorable circumstances, host detectable atmospheres.

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Activity and Rotation of Kepler-17

Válio

Estrela

Netto

et al. 2017

ApJ

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Magnetic activity on stars manifests itself in the form of dark spots on the stellar surface, that cause modulation of a few percent in the light curve of the star as it rotates. When a planet eclipses its host star, it might cross in front of one of these spots creating a "bump" in the transit light curve. By modelling these spot signatures, it is possible to determine the physical properties of the spots such as size, temperature, and location. In turn, the monitoring of the spots longitude provides estimates of the stellar rotation and differential rotation. This technique was applied to the star Kepler-17, a solar-type star orbited by a hot Jupiter. The model yields the following spot characteristics: average radius of 49 ± 10 Mm, temperatures of 5100 ± 300 K, and surface area coverage of 6 ± 4 %. The rotation period at the transit latitude, −5• , occulted by the planet was found to be 11.92 ± 0.05 d, slightly smaller than the out-of-transit average period of 12.4 ± 0.1 d. Adopting a solar like differential rotation, we estimated the differential rotation of Kepler-17 to be ∆Ω = 0.041 ± 0.005 rd/d, which is close to the solar value of 0.050 rd/d, and a relative differential rotation of ∆Ω/Ω = 8.0 ± 0.9 %. Since Kepler-17 is much more active than our Sun, it appears that for this star larger rotation rate is more effective in the generation of magnetic fields than shear.

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Stellar Magnetic Cycles in the Solar-Like Stars Kepler-17 and Kepler-63

Estrela

Válio

2016

ApJ

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The stellar magnetic field plays a crucial role in the star internal mechanisms, as in the interactions with its environment. The study of starspots provides information about the stellar magnetic field, and can characterise the cycle. Moreover, the analysis of solar-type stars is also useful to shed light onto the origin of the solar magnetic field. The objective of this work is to characterise the magnetic activity of stars. Here, we studied two solar-type stars Kepler-17 and Kepler-63 using two methods to estimate the magnetic cycle length. The first one characterises the spots (radius, intensity, and location) by fitting the small variations in the light curve of a star caused by the occultation of a spot during a planetary transit. This approach yields the number of spots present in the stellar surface and the flux deficit subtracted from the star by their presence during each transit. The second method estimates the activity from the excess in the residuals of the transit lightcurves. This excess is obtained by subtracting a spotless model transit from the lightcurve, and then integrating all the residuals during the transit. The presence of long term periodicity is estimated in both time series. With the first method, we obtained P cycle = 1.12 ± 0.16 yr (Kepler-17) and P cycle = 1.27 ± 0.16 yr (Kepler-63), and for the second approach the values are 1.35 ± 0.27 yr and 1.27 ± 0.12 yr, respectively. The results of both methods agree with each other and confirm their robustness.

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Disequilibrium Chemistry in Exoplanet Atmospheres Observed with the Hubble Space Telescope

Roudier

Swain

Gudipati

et al. 2021

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Literature on the theory of exoplanet atmospheric disequilibrium chemistry is rich, although its observational counterpart has yet to emerge beyond the hints provided by a few targets in dedicated studies. We report results from an uniform data reduction and analysis for a catalog of 62 Hubble Space Telescope exoplanet transit spectra where we assess the atmospheric model preference for disequilibrium chemistry (i.e., water vapor is not the dominant absorption spectral signature) over thermal equilibrium chemistry in a comparative planetology context. Where model preference assessment is possible, we find that disequilibrium occurs in about half of the atmospheres, indicating that disequilibrium processes play an important role in the composition of exoplanet atmospheres. While very hot atmospheres, over 1800 K, prefer equilibrium chemistry, we find a clustering of preference for disequilibrium in the 1200–1800 K temperature range. We suggest that UV-augmented thermochemistry may play a significant role for those atmospheres.

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Raissa Estrela

Detection of an Atmosphere on a Rocky Exoplanet

Activity and Rotation of Kepler-17

Stellar Magnetic Cycles in the Solar-Like Stars Kepler-17 and Kepler-63

Disequilibrium Chemistry in Exoplanet Atmospheres Observed with the Hubble Space Telescope

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