JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b

James Kirk; Kevin B. Stevenson; Guangwei Fu; Jacob Lustig-Yaeger; Sarah E. Moran; Sarah Peacock; Munazza K. Alam; Natasha E. Batalha; Katherine A. Bennett; Junellie Gonzalez-Quiles; Mercedes López-Morales; Joshua D. Lothringer; Ryan J. MacDonald; E. M. May; L. C. Mayorga; Zafar Rustamkulov; David K. Sing; Kristin S. Sotzen; Jeff A. Valenti; Hannah R. Wakeford

doi:10.3847/1538-3881/ad19df

JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b

James Kirk^*, Kevin B. Stevenson, Guangwei Fu, Jacob Lustig-Yaeger, Sarah E. Moran, Sarah Peacock, Munazza K. Alam, Natasha E. Batalha, Katherine A. Bennett, Junellie Gonzalez-Quiles, Mercedes López-Morales, Joshua D. Lothringer, Ryan J. MacDonald, E. M. May, L. C. Mayorga, Zafar Rustamkulov, David K. Sing, Kristin S. Sotzen, Jeff A. Valenti, Hannah R. Wakeford

^*Corresponding author for this work

School of Physics and Astronomy

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

Abstract

We present a JWST/NIRCam transmission spectrum from 3.9-5.0 μm of the recently-validated sub-Earth GJ 341b (R_p = 0.92 R_⊕, T_eq = 540 K) orbiting a nearby bright M1 star (d = 10.4 pc, K_mag =5.6). We use three independent pipelines to reduce the data from the three JWST visits and perform several tests to check for the significance of an atmosphere. Overall, our analysis does not uncover evidence of an atmosphere. Our null hypothesis tests find that none of our pipelines' transmission spectra can rule out a flat line, although there is weak evidence for a Gaussian feature in two spectra from different pipelines (at 2.3 and 2.9σ). However, the candidate features are seen at different wavelengths (4.3 μm vs 4.7 μm), and our retrieval analysis finds that different gas species can explain these features in the two reductions (CO₂ at 3.1σ compared to O₃ at 2.9σ), suggesting that they are not real astrophysical signals. Our forward model analysis rules out a low mean molecular weight atmosphere (< 350x solar metallicity) to at least 3σ, and disfavors CH₄-dominated atmospheres at 1-3σ, depending on the reduction. Instead, the forward models find our transmission spectra are consistent with no atmosphere, a hazy atmosphere, or an atmosphere containing a species that does not have prominent molecular bands across the NIRCam/F444W bandpass, such as a water-dominated atmosphere. Our results demonstrate the unequivocal need for two or more transit observations analyzed with multiple reduction pipelines, alongside rigorous statistical tests, to determine the robustness of molecular detections for small exoplanet atmospheres.

Original language	English
Article number	90
Number of pages	22
Journal	The Astronomical Journal
Volume	167
Issue number	3
Early online date	5 Feb 2024
DOIs	https://doi.org/10.3847/1538-3881/ad19df
Publication status	Published - 1 Mar 2024

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Kirk, J., Stevenson, K. B., Fu, G., Lustig-Yaeger, J., Moran, S. E., Peacock, S., Alam, M. K., Batalha, N. E., Bennett, K. A., Gonzalez-Quiles, J., López-Morales, M., Lothringer, J. D., MacDonald, R. J., May, E. M., Mayorga, L. C., Rustamkulov, Z., Sing, D. K., Sotzen, K. S., Valenti, J. A., & Wakeford, H. R. (2024). JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b. The Astronomical Journal, 167(3), Article 90. https://doi.org/10.3847/1538-3881/ad19df

@article{662d8ba4b5154ce08f19bfaad4187246,

title = "JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b",

abstract = "We present a JWST/NIRCam transmission spectrum from 3.9-5.0 μm of the recently-validated sub-Earth GJ 341b (Rp = 0.92 R⊕, Teq = 540 K) orbiting a nearby bright M1 star (d = 10.4 pc, Kmag =5.6). We use three independent pipelines to reduce the data from the three JWST visits and perform several tests to check for the significance of an atmosphere. Overall, our analysis does not uncover evidence of an atmosphere. Our null hypothesis tests find that none of our pipelines' transmission spectra can rule out a flat line, although there is weak evidence for a Gaussian feature in two spectra from different pipelines (at 2.3 and 2.9σ). However, the candidate features are seen at different wavelengths (4.3 μm vs 4.7 μm), and our retrieval analysis finds that different gas species can explain these features in the two reductions (CO2 at 3.1σ compared to O3 at 2.9σ), suggesting that they are not real astrophysical signals. Our forward model analysis rules out a low mean molecular weight atmosphere (< 350x solar metallicity) to at least 3σ, and disfavors CH4-dominated atmospheres at 1-3σ, depending on the reduction. Instead, the forward models find our transmission spectra are consistent with no atmosphere, a hazy atmosphere, or an atmosphere containing a species that does not have prominent molecular bands across the NIRCam/F444W bandpass, such as a water-dominated atmosphere. Our results demonstrate the unequivocal need for two or more transit observations analyzed with multiple reduction pipelines, alongside rigorous statistical tests, to determine the robustness of molecular detections for small exoplanet atmospheres.",

author = "James Kirk and Stevenson, {Kevin B.} and Guangwei Fu and Jacob Lustig-Yaeger and Moran, {Sarah E.} and Sarah Peacock and Alam, {Munazza K.} and Batalha, {Natasha E.} and Bennett, {Katherine A.} and Junellie Gonzalez-Quiles and Mercedes L{\'o}pez-Morales and Lothringer, {Joshua D.} and MacDonald, {Ryan J.} and May, {E. M.} and Mayorga, {L. C.} and Zafar Rustamkulov and Sing, {David K.} and Sotzen, {Kristin S.} and Valenti, {Jeff A.} and Wakeford, {Hannah R.}",

note = "Funding: J.K. acknowledges financial support from Imperial College London through an Imperial College Research Fellowship grant. ",

year = "2024",

month = mar,

day = "1",

doi = "10.3847/1538-3881/ad19df",

language = "English",

volume = "167",

journal = "The Astronomical Journal",

issn = "1538-3881",

publisher = "American Astronomical Society",

number = "3",

}

Kirk, J, Stevenson, KB, Fu, G, Lustig-Yaeger, J, Moran, SE, Peacock, S, Alam, MK, Batalha, NE, Bennett, KA, Gonzalez-Quiles, J, López-Morales, M, Lothringer, JD, MacDonald, RJ, May, EM, Mayorga, LC, Rustamkulov, Z, Sing, DK, Sotzen, KS, Valenti, JA & Wakeford, HR 2024, 'JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b', The Astronomical Journal, vol. 167, no. 3, 90. https://doi.org/10.3847/1538-3881/ad19df

TY - JOUR

T1 - JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b

AU - Kirk, James

AU - Stevenson, Kevin B.

AU - Fu, Guangwei

AU - Lustig-Yaeger, Jacob

AU - Moran, Sarah E.

AU - Peacock, Sarah

AU - Alam, Munazza K.

AU - Batalha, Natasha E.

AU - Bennett, Katherine A.

AU - Gonzalez-Quiles, Junellie

AU - López-Morales, Mercedes

AU - Lothringer, Joshua D.

AU - MacDonald, Ryan J.

AU - May, E. M.

AU - Mayorga, L. C.

AU - Rustamkulov, Zafar

AU - Sing, David K.

AU - Sotzen, Kristin S.

AU - Valenti, Jeff A.

AU - Wakeford, Hannah R.

N1 - Funding: J.K. acknowledges financial support from Imperial College London through an Imperial College Research Fellowship grant.

PY - 2024/3/1

Y1 - 2024/3/1

N2 - We present a JWST/NIRCam transmission spectrum from 3.9-5.0 μm of the recently-validated sub-Earth GJ 341b (Rp = 0.92 R⊕, Teq = 540 K) orbiting a nearby bright M1 star (d = 10.4 pc, Kmag =5.6). We use three independent pipelines to reduce the data from the three JWST visits and perform several tests to check for the significance of an atmosphere. Overall, our analysis does not uncover evidence of an atmosphere. Our null hypothesis tests find that none of our pipelines' transmission spectra can rule out a flat line, although there is weak evidence for a Gaussian feature in two spectra from different pipelines (at 2.3 and 2.9σ). However, the candidate features are seen at different wavelengths (4.3 μm vs 4.7 μm), and our retrieval analysis finds that different gas species can explain these features in the two reductions (CO2 at 3.1σ compared to O3 at 2.9σ), suggesting that they are not real astrophysical signals. Our forward model analysis rules out a low mean molecular weight atmosphere (< 350x solar metallicity) to at least 3σ, and disfavors CH4-dominated atmospheres at 1-3σ, depending on the reduction. Instead, the forward models find our transmission spectra are consistent with no atmosphere, a hazy atmosphere, or an atmosphere containing a species that does not have prominent molecular bands across the NIRCam/F444W bandpass, such as a water-dominated atmosphere. Our results demonstrate the unequivocal need for two or more transit observations analyzed with multiple reduction pipelines, alongside rigorous statistical tests, to determine the robustness of molecular detections for small exoplanet atmospheres.

AB - We present a JWST/NIRCam transmission spectrum from 3.9-5.0 μm of the recently-validated sub-Earth GJ 341b (Rp = 0.92 R⊕, Teq = 540 K) orbiting a nearby bright M1 star (d = 10.4 pc, Kmag =5.6). We use three independent pipelines to reduce the data from the three JWST visits and perform several tests to check for the significance of an atmosphere. Overall, our analysis does not uncover evidence of an atmosphere. Our null hypothesis tests find that none of our pipelines' transmission spectra can rule out a flat line, although there is weak evidence for a Gaussian feature in two spectra from different pipelines (at 2.3 and 2.9σ). However, the candidate features are seen at different wavelengths (4.3 μm vs 4.7 μm), and our retrieval analysis finds that different gas species can explain these features in the two reductions (CO2 at 3.1σ compared to O3 at 2.9σ), suggesting that they are not real astrophysical signals. Our forward model analysis rules out a low mean molecular weight atmosphere (< 350x solar metallicity) to at least 3σ, and disfavors CH4-dominated atmospheres at 1-3σ, depending on the reduction. Instead, the forward models find our transmission spectra are consistent with no atmosphere, a hazy atmosphere, or an atmosphere containing a species that does not have prominent molecular bands across the NIRCam/F444W bandpass, such as a water-dominated atmosphere. Our results demonstrate the unequivocal need for two or more transit observations analyzed with multiple reduction pipelines, alongside rigorous statistical tests, to determine the robustness of molecular detections for small exoplanet atmospheres.

U2 - 10.3847/1538-3881/ad19df

DO - 10.3847/1538-3881/ad19df

M3 - Article

SN - 1538-3881

VL - 167

JO - The Astronomical Journal

JF - The Astronomical Journal

IS - 3

M1 - 90

ER -

JWST/NIRCam transmission spectroscopy of the nearby sub-Earth GJ 341b

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