JWST TRAPPIST-1 e/b Program: Motivation and First Observations

Natalie H. Allen; Néstor Espinoza; V. A. Boehm; Caleb I. Cañas; Kevin B. Stevenson; Nikole K. Lewis; Ryan J. MacDonald; Brett M. Morris; Eric Agol; Knicole Colón; Hannah Diamond-Lowe; Ana Glidden; Amélie Gressier; Jingcheng Huang; Zifan Lin; Douglas Long; Dana R. Louie; Meredith A. MacGregor; Laurent Pueyo; Benjamin V. Rackham; Sukrit Ranjan; Sara Seager; Guadalupe Tovar Mendoza; Jeff A. Valenti; Daniel Valentine; Roeland P. van der Marel; Hannah R. Wakeford

doi:10.3847/1538-3881/ae28cb

JWST TRAPPIST-1 e/b Program: Motivation and First Observations

Natalie H. Allen^*, Néstor Espinoza, V. A. Boehm, Caleb I. Cañas, Kevin B. Stevenson, Nikole K. Lewis, Ryan J. MacDonald, Brett M. Morris, Eric Agol, Knicole Colón, Hannah Diamond-Lowe, Ana Glidden, Amélie Gressier, Jingcheng Huang, Zifan Lin, Douglas Long, Dana R. Louie, Meredith A. MacGregor, Laurent Pueyo, Benjamin V. RackhamSukrit Ranjan, Sara Seager, Guadalupe Tovar Mendoza, Jeff A. Valenti, Daniel Valentine, Roeland P. van der Marel, Hannah R. Wakeford

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

One of the forefront goals in the field of exoplanets is the detection of an atmosphere on a temperate terrestrial exoplanet, and among the best suited systems to do so is TRAPPIST-1. However, JWST transit observations of the TRAPPIST-1 planets show significant contamination from stellar surface features that we are unable to confidently model. Here, we present the motivation and first observations of our JWST multicycle program of TRAPPIST-1 e, which utilize close transits of the airless TRAPPIST-1 b to model-independently correct for stellar contamination, with the goal of determining whether TRAPPIST-1 e has an Earth-like mean molecular weight atmosphere containing CO2. We present our simulations, which show that with 15 close transit observations, we will be able to detect this atmosphere on TRAPPIST-1 e at ΔlnZ=5 or greater confidence assuming we are able to correct for stellar contamination using the close transit observations. We also show the first three observations of our program. We find that our ability to correct for stellar contamination can be inhibited when strong stellar flares are present, as flares can break the assumption that the star does not change meaningfully between planetary transits. The cleanest observation demonstrates the removal of stellar contamination contribution through an increased preference for a flat line over the original TRAPPIST-1 e spectrum, but highlights how minor data analysis assumptions can propagate significantly when searching for small atmospheric signals. This is amplified when using the signals from multiple planets, which is important to consider as we continue our atmospheric search.

Original language	English
Article number	105
Number of pages	21
Journal	The Astronomical Journal
Volume	171
Issue number	2
Early online date	22 Jan 2026
DOIs	https://doi.org/10.3847/1538-3881/ae28cb
Publication status	Published - 1 Feb 2026

Bibliographical note

Publisher Copyright:
© 2026. The Author(s).

Keywords

Exoplanet atmospheres
Exoplanets
Extrasolar rocky planets
Exoplanet astronomy

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Allen, N. H., Espinoza, N., Boehm, V. A., Cañas, C. I., Stevenson, K. B., Lewis, N. K., MacDonald, R. J., Morris, B. M., Agol, E., Colón, K., Diamond-Lowe, H., Glidden, A., Gressier, A., Huang, J., Lin, Z., Long, D., Louie, D. R., MacGregor, M. A., Pueyo, L., ... Wakeford, H. R. (2026). JWST TRAPPIST-1 e/b Program: Motivation and First Observations. The Astronomical Journal, 171(2), Article 105. https://doi.org/10.3847/1538-3881/ae28cb

@article{01128b903fd94819a88e2731631b06b7,

title = "JWST TRAPPIST-1 e/b Program: Motivation and First Observations",

abstract = "One of the forefront goals in the field of exoplanets is the detection of an atmosphere on a temperate terrestrial exoplanet, and among the best suited systems to do so is TRAPPIST-1. However, JWST transit observations of the TRAPPIST-1 planets show significant contamination from stellar surface features that we are unable to confidently model. Here, we present the motivation and first observations of our JWST multicycle program of TRAPPIST-1 e, which utilize close transits of the airless TRAPPIST-1 b to model-independently correct for stellar contamination, with the goal of determining whether TRAPPIST-1 e has an Earth-like mean molecular weight atmosphere containing CO2. We present our simulations, which show that with 15 close transit observations, we will be able to detect this atmosphere on TRAPPIST-1 e at ΔlnZ=5 or greater confidence assuming we are able to correct for stellar contamination using the close transit observations. We also show the first three observations of our program. We find that our ability to correct for stellar contamination can be inhibited when strong stellar flares are present, as flares can break the assumption that the star does not change meaningfully between planetary transits. The cleanest observation demonstrates the removal of stellar contamination contribution through an increased preference for a flat line over the original TRAPPIST-1 e spectrum, but highlights how minor data analysis assumptions can propagate significantly when searching for small atmospheric signals. This is amplified when using the signals from multiple planets, which is important to consider as we continue our atmospheric search.",

keywords = "Exoplanet atmospheres, Exoplanets, Extrasolar rocky planets, Exoplanet astronomy",

author = "Allen, \{Natalie H.\} and N{\'e}stor Espinoza and Boehm, \{V. A.\} and Ca{\~n}as, \{Caleb I.\} and Stevenson, \{Kevin B.\} and Lewis, \{Nikole K.\} and MacDonald, \{Ryan J.\} and Morris, \{Brett M.\} and Eric Agol and Knicole Col{\'o}n and Hannah Diamond-Lowe and Ana Glidden and Am{\'e}lie Gressier and Jingcheng Huang and Zifan Lin and Douglas Long and Louie, \{Dana R.\} and MacGregor, \{Meredith A.\} and Laurent Pueyo and Rackham, \{Benjamin V.\} and Sukrit Ranjan and Sara Seager and \{Tovar Mendoza\}, Guadalupe and Valenti, \{Jeff A.\} and Daniel Valentine and \{van der Marel\}, \{Roeland P.\} and Wakeford, \{Hannah R.\}",

note = "Publisher Copyright: {\textcopyright} 2026. The Author(s). ",

year = "2026",

month = feb,

day = "1",

doi = "10.3847/1538-3881/ae28cb",

language = "English",

volume = "171",

journal = "The Astronomical Journal",

issn = "0004-6256",

publisher = "American Astronomical Society",

number = "2",

}

Allen, NH, Espinoza, N, Boehm, VA, Cañas, CI, Stevenson, KB, Lewis, NK, MacDonald, RJ, Morris, BM, Agol, E, Colón, K, Diamond-Lowe, H, Glidden, A, Gressier, A, Huang, J, Lin, Z, Long, D, Louie, DR, MacGregor, MA, Pueyo, L, Rackham, BV, Ranjan, S, Seager, S, Tovar Mendoza, G, Valenti, JA, Valentine, D, van der Marel, RP & Wakeford, HR 2026, 'JWST TRAPPIST-1 e/b Program: Motivation and First Observations', The Astronomical Journal, vol. 171, no. 2, 105. https://doi.org/10.3847/1538-3881/ae28cb

TY - JOUR

T1 - JWST TRAPPIST-1 e/b Program

T2 - Motivation and First Observations

AU - Allen, Natalie H.

AU - Espinoza, Néstor

AU - Boehm, V. A.

AU - Cañas, Caleb I.

AU - Stevenson, Kevin B.

AU - Lewis, Nikole K.

AU - MacDonald, Ryan J.

AU - Morris, Brett M.

AU - Agol, Eric

AU - Colón, Knicole

AU - Diamond-Lowe, Hannah

AU - Glidden, Ana

AU - Gressier, Amélie

AU - Huang, Jingcheng

AU - Lin, Zifan

AU - Long, Douglas

AU - Louie, Dana R.

AU - MacGregor, Meredith A.

AU - Pueyo, Laurent

AU - Rackham, Benjamin V.

AU - Ranjan, Sukrit

AU - Seager, Sara

AU - Tovar Mendoza, Guadalupe

AU - Valenti, Jeff A.

AU - Valentine, Daniel

AU - van der Marel, Roeland P.

AU - Wakeford, Hannah R.

PY - 2026/2/1

Y1 - 2026/2/1

N2 - One of the forefront goals in the field of exoplanets is the detection of an atmosphere on a temperate terrestrial exoplanet, and among the best suited systems to do so is TRAPPIST-1. However, JWST transit observations of the TRAPPIST-1 planets show significant contamination from stellar surface features that we are unable to confidently model. Here, we present the motivation and first observations of our JWST multicycle program of TRAPPIST-1 e, which utilize close transits of the airless TRAPPIST-1 b to model-independently correct for stellar contamination, with the goal of determining whether TRAPPIST-1 e has an Earth-like mean molecular weight atmosphere containing CO2. We present our simulations, which show that with 15 close transit observations, we will be able to detect this atmosphere on TRAPPIST-1 e at ΔlnZ=5 or greater confidence assuming we are able to correct for stellar contamination using the close transit observations. We also show the first three observations of our program. We find that our ability to correct for stellar contamination can be inhibited when strong stellar flares are present, as flares can break the assumption that the star does not change meaningfully between planetary transits. The cleanest observation demonstrates the removal of stellar contamination contribution through an increased preference for a flat line over the original TRAPPIST-1 e spectrum, but highlights how minor data analysis assumptions can propagate significantly when searching for small atmospheric signals. This is amplified when using the signals from multiple planets, which is important to consider as we continue our atmospheric search.

AB - One of the forefront goals in the field of exoplanets is the detection of an atmosphere on a temperate terrestrial exoplanet, and among the best suited systems to do so is TRAPPIST-1. However, JWST transit observations of the TRAPPIST-1 planets show significant contamination from stellar surface features that we are unable to confidently model. Here, we present the motivation and first observations of our JWST multicycle program of TRAPPIST-1 e, which utilize close transits of the airless TRAPPIST-1 b to model-independently correct for stellar contamination, with the goal of determining whether TRAPPIST-1 e has an Earth-like mean molecular weight atmosphere containing CO2. We present our simulations, which show that with 15 close transit observations, we will be able to detect this atmosphere on TRAPPIST-1 e at ΔlnZ=5 or greater confidence assuming we are able to correct for stellar contamination using the close transit observations. We also show the first three observations of our program. We find that our ability to correct for stellar contamination can be inhibited when strong stellar flares are present, as flares can break the assumption that the star does not change meaningfully between planetary transits. The cleanest observation demonstrates the removal of stellar contamination contribution through an increased preference for a flat line over the original TRAPPIST-1 e spectrum, but highlights how minor data analysis assumptions can propagate significantly when searching for small atmospheric signals. This is amplified when using the signals from multiple planets, which is important to consider as we continue our atmospheric search.

KW - Exoplanet atmospheres

KW - Exoplanets

KW - Extrasolar rocky planets

KW - Exoplanet astronomy

U2 - 10.3847/1538-3881/ae28cb

DO - 10.3847/1538-3881/ae28cb

M3 - Article (Academic Journal)

SN - 0004-6256

VL - 171

JO - The Astronomical Journal

JF - The Astronomical Journal

IS - 2

M1 - 105

ER -

JWST TRAPPIST-1 e/b Program: Motivation and First Observations

Abstract

Bibliographical note

Keywords

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