Possible Carbon Dioxide above the Thick Aerosols of GJ1214b

Everett Schlawin; Kazumasa Ohno; Taylor J. Bell; Matthew M. Murphy; Luis Welbanks; Thomas G. Beatty; Thomas P. Greene; Jonathan J. Fortney; Vivien Parmentier; Isaac R. Edelman; Samuel Gill; David R. Anderson; Peter J. Wheatley; Gregory W. Henry; Nishil Mehta; Laura Kreidberg; Marcia J. Rieke

doi:10.3847/2041-8213/ad7fef

Possible Carbon Dioxide above the Thick Aerosols of GJ1214b

Everett Schlawin, Kazumasa Ohno, Taylor J. Bell, Matthew M. Murphy, Luis Welbanks, Thomas G. Beatty, Thomas P. Greene, Jonathan J. Fortney, Vivien Parmentier, Isaac R. Edelman, Samuel Gill, David R. Anderson, Peter J. Wheatley, Gregory W. Henry, Nishil Mehta, Laura Kreidberg, Marcia J. Rieke

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Sub-Neptune planets with radii smaller than Neptune (3.9 R_⊕) are the most common type of planet known to exist in the Milky Way, even though they are absent in the solar system. These planets can potentially have a large diversity of compositions as a result of different mixtures of rocky material, icy material, and gas accreted from a protoplanetary disk. However, the bulk density of a sub-Neptune, informed by its mass and radius alone, cannot uniquely constrain its composition; atmospheric spectroscopy is necessary. GJ 1214 b, which hosts an atmosphere that is potentially the most favorable for spectroscopic detection of any sub-Neptune, is instead enshrouded in aerosols (thus showing no spectroscopic features), hiding its composition from view at previously observed wavelengths in its terminator. Here, we present a JWST NIRSpec transmission spectrum from 2.8 to 5.1 μm that shows signatures of CO₂ and CH₄, expected at high metallicity. A model containing both these molecules is preferred by 3.3σ and 3.6σ as compared to a featureless spectrum for two different data analysis pipelines, respectively. Given the low signal-to-noise of the features compared to the continuum, however, more observations are needed to confirm the CO₂ and CH₄ signatures and better constrain other diagnostic features in the near-infrared. Further modeling of the planet’s atmosphere, interior structure and origins will provide valuable insights about how sub-Neptunes like GJ 1214 b form and evolve.

Original language	English (US)
Article number	L33
Journal	Astrophysical Journal Letters
Volume	974
Issue number	2
DOIs	https://doi.org/10.3847/2041-8213/ad7fef
State	Published - Oct 1 2024

Keywords

Exoplanet atmospheres (487)
James Webb Space Telescope (2291)
Mini Neptunes (1063)
Transmission spectroscopy (2133)
Unified Astronomy Thesaurus concepts: Exoplanet atmospheric composition (2021)

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/2041-8213/ad7fef

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Schlawin, E., Ohno, K., Bell, T. J., Murphy, M. M., Welbanks, L., Beatty, T. G., Greene, T. P., Fortney, J. J., Parmentier, V., Edelman, I. R., Gill, S., Anderson, D. R., Wheatley, P. J., Henry, G. W., Mehta, N., Kreidberg, L., & Rieke, M. J. (2024). Possible Carbon Dioxide above the Thick Aerosols of GJ1214b. Astrophysical Journal Letters, 974(2), Article L33. https://doi.org/10.3847/2041-8213/ad7fef

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title = "Possible Carbon Dioxide above the Thick Aerosols of GJ1214b",

abstract = "Sub-Neptune planets with radii smaller than Neptune (3.9 R⊕) are the most common type of planet known to exist in the Milky Way, even though they are absent in the solar system. These planets can potentially have a large diversity of compositions as a result of different mixtures of rocky material, icy material, and gas accreted from a protoplanetary disk. However, the bulk density of a sub-Neptune, informed by its mass and radius alone, cannot uniquely constrain its composition; atmospheric spectroscopy is necessary. GJ 1214 b, which hosts an atmosphere that is potentially the most favorable for spectroscopic detection of any sub-Neptune, is instead enshrouded in aerosols (thus showing no spectroscopic features), hiding its composition from view at previously observed wavelengths in its terminator. Here, we present a JWST NIRSpec transmission spectrum from 2.8 to 5.1 μm that shows signatures of CO2 and CH4, expected at high metallicity. A model containing both these molecules is preferred by 3.3σ and 3.6σ as compared to a featureless spectrum for two different data analysis pipelines, respectively. Given the low signal-to-noise of the features compared to the continuum, however, more observations are needed to confirm the CO2 and CH4 signatures and better constrain other diagnostic features in the near-infrared. Further modeling of the planet{\textquoteright}s atmosphere, interior structure and origins will provide valuable insights about how sub-Neptunes like GJ 1214 b form and evolve.",

keywords = "Exoplanet atmospheres (487), James Webb Space Telescope (2291), Mini Neptunes (1063), Transmission spectroscopy (2133), Unified Astronomy Thesaurus concepts: Exoplanet atmospheric composition (2021)",

author = "Everett Schlawin and Kazumasa Ohno and Bell, {Taylor J.} and Murphy, {Matthew M.} and Luis Welbanks and Beatty, {Thomas G.} and Greene, {Thomas P.} and Fortney, {Jonathan J.} and Vivien Parmentier and Edelman, {Isaac R.} and Samuel Gill and Anderson, {David R.} and Wheatley, {Peter J.} and Henry, {Gregory W.} and Nishil Mehta and Laura Kreidberg and Rieke, {Marcia J.}",

note = "Publisher Copyright: {\textcopyright} 2024. The Author(s).",

year = "2024",

month = oct,

day = "1",

doi = "10.3847/2041-8213/ad7fef",

language = "English (US)",

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T1 - Possible Carbon Dioxide above the Thick Aerosols of GJ1214b

AU - Schlawin, Everett

AU - Ohno, Kazumasa

AU - Bell, Taylor J.

AU - Murphy, Matthew M.

AU - Welbanks, Luis

AU - Beatty, Thomas G.

AU - Greene, Thomas P.

AU - Fortney, Jonathan J.

AU - Parmentier, Vivien

AU - Edelman, Isaac R.

AU - Gill, Samuel

AU - Anderson, David R.

AU - Wheatley, Peter J.

AU - Henry, Gregory W.

AU - Mehta, Nishil

AU - Kreidberg, Laura

AU - Rieke, Marcia J.

PY - 2024/10/1

Y1 - 2024/10/1

N2 - Sub-Neptune planets with radii smaller than Neptune (3.9 R⊕) are the most common type of planet known to exist in the Milky Way, even though they are absent in the solar system. These planets can potentially have a large diversity of compositions as a result of different mixtures of rocky material, icy material, and gas accreted from a protoplanetary disk. However, the bulk density of a sub-Neptune, informed by its mass and radius alone, cannot uniquely constrain its composition; atmospheric spectroscopy is necessary. GJ 1214 b, which hosts an atmosphere that is potentially the most favorable for spectroscopic detection of any sub-Neptune, is instead enshrouded in aerosols (thus showing no spectroscopic features), hiding its composition from view at previously observed wavelengths in its terminator. Here, we present a JWST NIRSpec transmission spectrum from 2.8 to 5.1 μm that shows signatures of CO2 and CH4, expected at high metallicity. A model containing both these molecules is preferred by 3.3σ and 3.6σ as compared to a featureless spectrum for two different data analysis pipelines, respectively. Given the low signal-to-noise of the features compared to the continuum, however, more observations are needed to confirm the CO2 and CH4 signatures and better constrain other diagnostic features in the near-infrared. Further modeling of the planet’s atmosphere, interior structure and origins will provide valuable insights about how sub-Neptunes like GJ 1214 b form and evolve.

AB - Sub-Neptune planets with radii smaller than Neptune (3.9 R⊕) are the most common type of planet known to exist in the Milky Way, even though they are absent in the solar system. These planets can potentially have a large diversity of compositions as a result of different mixtures of rocky material, icy material, and gas accreted from a protoplanetary disk. However, the bulk density of a sub-Neptune, informed by its mass and radius alone, cannot uniquely constrain its composition; atmospheric spectroscopy is necessary. GJ 1214 b, which hosts an atmosphere that is potentially the most favorable for spectroscopic detection of any sub-Neptune, is instead enshrouded in aerosols (thus showing no spectroscopic features), hiding its composition from view at previously observed wavelengths in its terminator. Here, we present a JWST NIRSpec transmission spectrum from 2.8 to 5.1 μm that shows signatures of CO2 and CH4, expected at high metallicity. A model containing both these molecules is preferred by 3.3σ and 3.6σ as compared to a featureless spectrum for two different data analysis pipelines, respectively. Given the low signal-to-noise of the features compared to the continuum, however, more observations are needed to confirm the CO2 and CH4 signatures and better constrain other diagnostic features in the near-infrared. Further modeling of the planet’s atmosphere, interior structure and origins will provide valuable insights about how sub-Neptunes like GJ 1214 b form and evolve.

KW - Exoplanet atmospheres (487)

KW - James Webb Space Telescope (2291)

KW - Mini Neptunes (1063)

KW - Transmission spectroscopy (2133)

KW - Unified Astronomy Thesaurus concepts: Exoplanet atmospheric composition (2021)

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SN - 2041-8205

VL - 974

JO - Astrophysical Journal Letters

JF - Astrophysical Journal Letters

IS - 2

M1 - L33

ER -

Possible Carbon Dioxide above the Thick Aerosols of GJ1214b

Abstract

Keywords

ASJC Scopus subject areas

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