Atmospheric reconnaissance of the habitable-zone Earth-sized planets orbiting TRAPPIST-1

Wit, Julien de; Wakeford, Hannah R.; Lewis, Nikole K.; Delrez, Laetitia; Gillon, M.; Selsis, F.; Leconte, Jérémy; Demory, Brice-Olivier; Belmont, E.; Bourrier, V.; Burgasser, Adam J.; Grimm, Simon L.; Jehin, Emmanuël; Lederer, Susan M.; Owen, James E.; Stamenković, V.; Triaud, A. H. M. J.

doi:10.1038/s41550-017-0374-z

Cited by 219 publications

(215 citation statements)

References 35 publications

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“…Although methods exist to correct the WFC3 first-orbit systematics (e.g. Zhou et al 2017;de Wit et al 2018), we opted for this approach to be consistent with our previous analyses (Evans et al 2016(Evans et al , 2017 and to avoid modeling the baseline trend over the full fiveorbit visits, which is less likely to be well approximated as linear. The resulting four-orbit white light curves were fit using a similar methodology to that described in Evans et al (2017), in which the systematics are treated as a Gaussian process (GP).…”

Section: White Light Curve Analysesmentioning

confidence: 99%

An emission spectrum for WASP-121b measured across the 0.8–1.1 μm wavelength range using the Hubble Space Telescope

Evans

Sing

Goyal

et al. 2019

Monthly Notices of the Royal Astronomical Society

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WASP-121b is a transiting gas giant exoplanet orbiting close to its Roche limit, with an inflated radius nearly double that of Jupiter and a dayside temperature comparable to a late M dwarf photosphere. Secondary eclipse observations covering the 1.1-1.6 µm wavelength range have revealed an atmospheric thermal inversion on the dayside hemisphere, likely caused by high altitude absorption at optical wavelengths. Here we present secondary eclipse observations made with the Hubble Space Telescope Wide Field Camera 3 spectrograph that extend the wavelength coverage from 1.1 µm down to 0.8 µm. To determine the atmospheric properties from the measured eclipse spectrum, we performed a retrieval analysis assuming chemical equilibrium, with the effects of thermal dissociation and ionization included. Our best-fit model provides a good fit to the data with reduced χ 2 ν = 1.04. The data diverge from a blackbody spectrum and instead exhibit emission due to H − shortward of 1.1 µm. The best-fit model does not reproduce a previously reported bump in the spectrum at 1.25µm, possibly indicating this feature is a statistical fluctuation in the data rather than a VO emission band as had been tentatively suggested. We estimate an atmospheric metallicity of [M/H] = 1.09 +0.57 −0.69 , and fit for the carbon and oxygen abundances separately, obtaining [C/H] = −0.29 +0.61 −0.48 and [O/H] = 0.18 +0.64 −0.60 . The corresponding carbon-tooxygen ratio is C/O = 0.49 +0.65 −0.37 , which encompasses the solar value of 0.54, but has a large uncertainty.

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Section: White Light Curve Analysesmentioning

confidence: 99%

An emission spectrum for WASP-121b measured across the 0.8–1.1 μm wavelength range using the Hubble Space Telescope

Evans

Sing

Goyal

et al. 2019

Monthly Notices of the Royal Astronomical Society

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“…The combined spectrum of the planets rules out cloud-free, hydrogen-dominated atmospheres, except for TRAPPIST-1 f and 1 g (de Wit et al 2018;Moran et al 2018); Wakeford et al (2019) recently suggested that a clear hydrogen-dominated atmosphere may be ruled out for TRAPPIST-1 g. Since high-altitude clouds and haze are not expected to form in hydrogen-dominated atmospheres around temperate planets (e.g. Morley et al 2015), transit spectroscopy of the TRAPPIST-1 planets suggests no atmosphere or a high-metallicity atmosphere referred to as a secondary atmosphere.…”

Section: Introductionmentioning

confidence: 95%

“…Hubble Space Telescope (HST)/Wide Field Camera 3 (WFC3) measurements exhibit no prominent absorption features at near-infrared wavelengths in transmission spectra of six of the TRAPPIST-1 planets (de Wit et al 2016(de Wit et al , 2018Zhang et al 2018;Burdanov et al 2019)…”

Section: Introductionmentioning

confidence: 99%

Do the TRAPPIST-1 Planets Have Hydrogen-rich Atmospheres?

Hori

Ogihara

2020

ApJ

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Recently, transmission spectroscopy in the atmospheres of the TRAPPIST-1 planets revealed flat and featureless absorption spectra, which rule out cloud-free, hydrogen-dominated atmospheres. Earthsized planets orbiting TRAPPIST-1 likely have either a clear or a cloudy/hazy, hydrogen-poor atmosphere. In this paper, we investigate whether a proposed formation scenario is consistent with expected atmospheric compositions of the TRAPPIST-1 planets. We examine the amount of a hydrogen-rich gas that TRAPPIST-1-like planets accreted from the ambient disk until disk dispersal. Since TRAPPIST-1 planets are trapped into a resonant chain, we simulate disk gas accretion onto a migrating TRAPPIST-1-like planet. We find that the amount of an accreted hydrogen-rich gas is as small as 10 −2 wt% and 0.1 wt% for TRAPPIST-1 b and 1 c, 10 −2 wt% for 1 d, 1 wt% for 1 e, a few wt% for 1 f and 1 g and 1 wt% for 1 h, respectively. We also calculate the long-term thermal evolution of TRAPPIST-1-like planets after disk dissipation and estimate the mass loss of their hydrogen-rich atmospheres driven by a stellar X-ray and UV irradiation. We find that all the accreted hydrogen-rich atmospheres can be lost via hydrodynamic escape. Therefore, we conclude that TRAPPIST-1 planets should have no primordial hydrogen-rich gases but secondary atmospheres such as a Venus-like one and water vapor, if they currently retain atmospheres.

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“…Orbiting small stars, these planets provide an accelerated path toward finding and characterizing potentially habitable worlds. The TRAPPIST-1 planets already have transmission spectra measured by Hubble (de Wit et al 2018;Zhang et al 2018). With >7 times more collecting area and infrared instruments, the James Webb Space Telescope (JWST) will be capable of providing a more detailed look into the atmosphere of these cold exoplanets (Beichman et al 2014).…”

Section: Introductionmentioning

confidence: 99%

O₂- and CO-rich Atmospheres for Potentially Habitable Environments on TRAPPIST-1 Planets

Peterson

Wolf

2020

ApJ

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Small exoplanets of nearby M dwarf stars present the possibility to find and characterize habitable worlds within the next decade. TRAPPIST-1, an ultracool M dwarf star, was recently found to have seven Earth-sized planets of predominantly rocky composition. The planets e, f, and g can have a liquid water ocean on their surface given appropriate atmospheres of N2 and CO2. Particularly, climate models have shown that the planets e and f can sustain a global liquid water ocean, for ≥0.2 bar CO2 plus 1 bar N2, or ≥2 bars CO2, respectively. These atmospheres are irradiated by ultraviolet emission from the star's moderately active chromosphere, and the consequence of this irradiation is unknown. Here we show that chemical reactions driven by the irradiation can produce and maintain more than 0.2 bar O2 and 0.05 bar CO if the CO2 is ≥0.1 bar. The abundance of O2 and CO can rise to more than 1 bar under certain boundary conditions. Because of this O2-CO runaway, habitable environments on the TRAPPIST-1 planets entail an O2-and CO-rich atmosphere with coexisting O3. The only process that would prevent the runaway is direct recombination of O2 and CO in the ocean, a reaction that is facilitated biologically. Our results indicate that O2, O3, and CO should be considered together with CO2 as the primary molecules in the search for atmospheric signatures from temperate and rocky planets of TRAPPIST-1 and other M dwarf stars.

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Atmospheric reconnaissance of the habitable-zone Earth-sized planets orbiting TRAPPIST-1

Cited by 219 publications

References 35 publications

An emission spectrum for WASP-121b measured across the 0.8–1.1 μm wavelength range using the Hubble Space Telescope

An emission spectrum for WASP-121b measured across the 0.8–1.1 μm wavelength range using the Hubble Space Telescope

Do the TRAPPIST-1 Planets Have Hydrogen-rich Atmospheres?

O₂- and CO-rich Atmospheres for Potentially Habitable Environments on TRAPPIST-1 Planets

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Atmospheric reconnaissance of the habitable-zone Earth-sized planets orbiting TRAPPIST-1

Cited by 219 publications

References 35 publications

An emission spectrum for WASP-121b measured across the 0.8–1.1 μm wavelength range using the Hubble Space Telescope

An emission spectrum for WASP-121b measured across the 0.8–1.1 μm wavelength range using the Hubble Space Telescope

Do the TRAPPIST-1 Planets Have Hydrogen-rich Atmospheres?

O2- and CO-rich Atmospheres for Potentially Habitable Environments on TRAPPIST-1 Planets

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Product

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O₂- and CO-rich Atmospheres for Potentially Habitable Environments on TRAPPIST-1 Planets