Sulfur Hazes in Giant Exoplanet Atmospheres: Impacts on Reflected Light Spectra

Gao, Peter; Marley, Mark S.; Zahnle, Kevin; Robinson, Tyler D.; Lewis, Nikole K.

doi:10.3847/1538-3881/aa5fab

Cited by 83 publications

(70 citation statements)

References 100 publications

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“…Besides hydrocarbon haze, the existence of other aerosols can mute spectral features in transmission: condensation clouds such as KCl, ZnS, K 2 SO 4 , ZnO, and graphite clouds in the temperature range of interest in this study ( 1000 K) (Miller-Ricci Kempton et al 2012;Morley et al 2013;Mbarek & Kempton 2016;Ohno & Okuzumi 2018;Gao & Benneke 2018;Ormel & Min 2019) and photochemical haze made of sulfur species (Hu et al 2013;Zahnle et al 2016;Gao et al 2017).…”

Section: Discussionmentioning

confidence: 98%

Detectable Molecular Features above Hydrocarbon Haze via Transmission Spectroscopy with JWST: Case Studies of GJ 1214b-, GJ 436b-, HD 97658b-, and Kepler-51b-like Planets

Kawashima

Ikoma

2019

ApJL

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Some of the exoplanets so far observed show featureless or flat transmission spectra, possibly indicating the existence of clouds and/or haze in their atmospheres. Thanks to its large aperture size and broad wavelength coverage, JWST is expected to enable detailed investigation of exoplanet atmospheres, which could provide important constraints on the atmospheric composition obscured by clouds/haze. Here, we use four warm ( 1000 K) planets suitable for atmospheric characterization via transmission spectroscopy, GJ 1214b, GJ 436b, HD 97658b, and Kepler-51b, as examples to explore molecular absorption features detectable by JWST even in the existence of hydrocarbon haze in the atmospheres. We simulate photochemistry, the growth of hydrocarbon haze particles, and transmission spectra for the atmospheres of these four planets. Among the planetary parameters considered, super-Earths with hazy, relatively hydrogen-rich atmospheres are mostly expected to produce detectable molecular absorption features such as a quite prominent CH 4 feature at 3.3 µm even for the extreme case of the most efficient production of photochemical haze. For a planet that has extremely low gravity, such as Kepler-51b, haze particles grow significantly large in the upper atmosphere due to the small sedimentation velocity, resulting in the featureless or flat transmission spectrum in a wide wavelength range. This investigation shows that the transmission spectra with muted features measured by HST in most cases do not preclude strong features at the longer wavelengths accessible by JWST.

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Section: Discussionmentioning

confidence: 98%

Detectable Molecular Features above Hydrocarbon Haze via Transmission Spectroscopy with JWST: Case Studies of GJ 1214b-, GJ 436b-, HD 97658b-, and Kepler-51b-like Planets

Kawashima

Ikoma

2019

ApJL

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“…As for oxygen, its elemental abundance is harder to constrain as water is so much out of equilibrium on Jupiter (and the probe fell into a hot presumably dry spot and did not finish it's measurements). For exoplanet analysis, it has been a popular assumption to use solar metallicity Fortney et al 2006;Fortney 2007;Fortney et al 2008;Venot et al 2012;Moses et al 2011;Koskinen et al 2013;Zahnle & Marley 2014;Wakeford & Sing 2015;Heng 2016;Kataria et al 2016;Barstow et al 2017;Gao et al 2017), or a linear scaling of solar metallicity (Freedman et al 2014;Kataria et al 2015;Charnay et al 2015;Wakeford et al 2017), and hence why we chose to model it as one of our metallicity cases. The bulk composition of a planet's atmosphere plays a major role in the chemistry at work in the planet's atmosphere.…”

Section: Resultsmentioning

confidence: 99%

A Comparison of Simulated JWST Observations Derived from Equilibrium and Non-equilibrium Chemistry Models of Giant Exoplanets

Blumenthal

Mandell

Hébrard

et al. 2018

ApJ

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We aim to see if the difference between equilibrium and disequilibrium chemistry is observable in the atmospheres of transiting planets by the James Webb Space Telescope (JWST). We perform a case study comparing the dayside emission spectra of three planets like HD 189733b, WASP-80b, and GJ436b, in and out of chemical equilibrium at two metallicities each. These three planets were chosen because they span a large range of planetary masses and equilibrium temperatures, from hot and Jupiter-sized to warm and Neptune-sized. We link the one-dimensional disequilibrium chemistry model from Venot et al. (2012) in which thermochemical kinetics, vertical transport, and photochemistry are taken into account, to the one-dimensional, pseudo line-by-line radiative transfer model, Pyrat Bay, developed especially for hot Jupiters, and then simulate JWST spectra using PandExo for comparing the effects of temperature, metallicity, and radius. We find the most significant differences from 4 to 5 µm due to disequilibrium from CO and CO 2 abundances, and also H 2 O for select cases. Our case study shows a certain "sweet spot" of planetary mass, temperature, and metallicity where the difference between equilibrium and disequilibrium is observable. For a planet similar to WASP-80b, JWST's NIRSpec G395M can detect differences due to disequilibrium chemistry with one eclipse event. For a planet similar to GJ 436b, the observability of differences due to disequilibrium chemistry is possible at low metallicity given five eclipse events, but not possible at the higher metallicity.

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“…Carbon-binding materials never dominate the cloud particle material in the summarised cases where C/O changes from oxygen-rich (C/O=0.54) to carbon-rich (C/O=1.1), except for the warm model for C/O=2.0. Sulfur haze has been suggested to emerge in cold gas giants (<700K, Gao et al 2017). An overabundance of sulfur was confirmed for Uranus (H2S ice particles detected, see de Pater 2018), and volcanic sulfur as trigger for snowball Earth (Macdonald & Wordsworth 2017).…”

Section: Exoplanet Element Abundances and Mineralogic Ratiosmentioning

confidence: 99%

Exoplanet Clouds

Helling

2019

Annu. Rev. Earth Planet. Sci.

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Clouds also form in atmospheres of planets that orbit other stars than our Sun, in so-called extrasolar planets or exoplanets. Exoplanet atmospheres can be chemically extremely rich. Exoplanet clouds are therefor made of a mix of materials that changes throughout the atmosphere. They affect the atmospheres through element depletion and through absorption and scattering, hence, they have a profound impact on the atmosphere's energy budget. While astronomical observations point us to the presence of extrasolar clouds and make first suggestions on particle sizes and material compositions, we require fundamental and complex modelling work to merge the individual observations into a coherent picture. Part of this is to develop an understanding for cloud formation in non-terrestrial environments.

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Sulfur Hazes in Giant Exoplanet Atmospheres: Impacts on Reflected Light Spectra

Cited by 83 publications

References 100 publications

Detectable Molecular Features above Hydrocarbon Haze via Transmission Spectroscopy with JWST: Case Studies of GJ 1214b-, GJ 436b-, HD 97658b-, and Kepler-51b-like Planets

Detectable Molecular Features above Hydrocarbon Haze via Transmission Spectroscopy with JWST: Case Studies of GJ 1214b-, GJ 436b-, HD 97658b-, and Kepler-51b-like Planets

A Comparison of Simulated JWST Observations Derived from Equilibrium and Non-equilibrium Chemistry Models of Giant Exoplanets

Exoplanet Clouds

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