Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b

P. C. August; L. A. Buchhave; H. Diamond-Lowe; J. M. Mendonça; A. Gressier; A. D. Rathcke; N. H. Allen; M. Fortune; K. D. Jones; E. A. Meier Valdés; B. O. Demory; N. Espinoza; C. E. Fisher; N. P. Gibson; K. Heng; J. Hoeijmakers; M. J. Hooton; D. Kitzmann; B. Prinoth; J. D. Eastman; R. Barnes

doi:10.1051/0004-6361/202452611

Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b

P. C. August^*, L. A. Buchhave, H. Diamond-Lowe, J. M. Mendonça, A. Gressier, A. D. Rathcke, N. H. Allen, M. Fortune, K. D. Jones, E. A. Meier Valdés, B. O. Demory, N. Espinoza, C. E. Fisher, N. P. Gibson, K. Heng, J. Hoeijmakers, M. J. Hooton, D. Kitzmann, B. Prinoth, J. D. EastmanR. Barnes

^*Corresponding author for this work

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Abstract

Context. M-dwarf systems offer an opportunity to study terrestrial exoplanetary atmospheres due to their small size and cool temperatures. However, the extreme conditions imposed by these host stars raise a question about whether their close-in rocky planets are able to retain any atmosphere at all. Aims. The Hot Rocks Survey aims to answer this question by targeting nine different M-dwarf rocky planets spanning a range of planetary and stellar properties. Of these, LHS 1478 b orbits an M3-type star, has an equilibrium temperature of Teq = 585 K, and receives 21 times Earth's instellation. Methods. We observed two secondary eclipses of LHS 1478 b using photometric imaging at 15 μm using the Mid-Infrared Instrument on the James Webb Space Telescope (JWST MIRI) to measure thermal emission from the dayside of the planet. We compared these values to atmospheric models to evaluate potential heat transport and CO₂absorption signatures. Results. We find that a secondary eclipse depth of 138 ± 53 ppm at the expected time for a circular orbit is preferred over a null model at 2.8σ, a moderate detection, though dynamical models do favour a non-eccentric orbit for this planet. The second observation results in a non-detection due to significantly larger unexplained systematics. Based on the first observation alone, we can reject the null hypothesis of the dark (zero Bond albedo) no atmosphere bare rock model with a confidence level of 3.3σ, though for AB = 0.2 the significance decreases to 2.1σ. The tentative secondary eclipse depth is consistent with the majority of the atmospheric scenarios we considered, spanning CO₂-rich atmospheres with surface pressures from 0.1 to 10 bar. However, we stress that the two observations from our programme do not yield consistent results, and more observations are needed to verify our findings. The Hot Rocks Survey serves as a relevant primer for future endeavours such as the Director's Discretionary Time (DDT) Rocky Worlds programme.

Original language	English
Article number	A171
Journal	Astronomy and Astrophysics
Volume	695
Number of pages	15
ISSN	0004-6361
DOIs	https://doi.org/10.1051/0004-6361/202452611
Publication status	Published - 2025

Keywords

Planets and satellites: atmospheres
Planets and satellites: terrestrial planets
Techniques: photometric

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August, P. C., Buchhave, L. A., Diamond-Lowe, H., Mendonça, J. M., Gressier, A., Rathcke, A. D., Allen, N. H., Fortune, M., Jones, K. D., Meier Valdés, E. A., Demory, B. O., Espinoza, N., Fisher, C. E., Gibson, N. P., Heng, K., Hoeijmakers, J., Hooton, M. J., Kitzmann, D., Prinoth, B., ... Barnes, R. (2025). Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b. Astronomy and Astrophysics, 695, Article A171. https://doi.org/10.1051/0004-6361/202452611

@article{2265f1e3e9994245a01183d0a0d82a79,

title = "Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b",

abstract = "Context. M-dwarf systems offer an opportunity to study terrestrial exoplanetary atmospheres due to their small size and cool temperatures. However, the extreme conditions imposed by these host stars raise a question about whether their close-in rocky planets are able to retain any atmosphere at all. Aims. The Hot Rocks Survey aims to answer this question by targeting nine different M-dwarf rocky planets spanning a range of planetary and stellar properties. Of these, LHS 1478 b orbits an M3-type star, has an equilibrium temperature of Teq = 585 K, and receives 21 times Earth's instellation. Methods. We observed two secondary eclipses of LHS 1478 b using photometric imaging at 15 μm using the Mid-Infrared Instrument on the James Webb Space Telescope (JWST MIRI) to measure thermal emission from the dayside of the planet. We compared these values to atmospheric models to evaluate potential heat transport and CO2 absorption signatures. Results. We find that a secondary eclipse depth of 138 ± 53 ppm at the expected time for a circular orbit is preferred over a null model at 2.8σ, a moderate detection, though dynamical models do favour a non-eccentric orbit for this planet. The second observation results in a non-detection due to significantly larger unexplained systematics. Based on the first observation alone, we can reject the null hypothesis of the dark (zero Bond albedo) no atmosphere bare rock model with a confidence level of 3.3σ, though for AB = 0.2 the significance decreases to 2.1σ. The tentative secondary eclipse depth is consistent with the majority of the atmospheric scenarios we considered, spanning CO2-rich atmospheres with surface pressures from 0.1 to 10 bar. However, we stress that the two observations from our programme do not yield consistent results, and more observations are needed to verify our findings. The Hot Rocks Survey serves as a relevant primer for future endeavours such as the Director's Discretionary Time (DDT) Rocky Worlds programme.",

keywords = "Planets and satellites: atmospheres, Planets and satellites: terrestrial planets, Techniques: photometric",

author = "August, {P. C.} and Buchhave, {L. A.} and H. Diamond-Lowe and Mendon{\c c}a, {J. M.} and A. Gressier and Rathcke, {A. D.} and Allen, {N. H.} and M. Fortune and Jones, {K. D.} and {Meier Vald{\'e}s}, {E. A.} and Demory, {B. O.} and N. Espinoza and Fisher, {C. E.} and Gibson, {N. P.} and K. Heng and J. Hoeijmakers and Hooton, {M. J.} and D. Kitzmann and B. Prinoth and Eastman, {J. D.} and R. Barnes",

year = "2025",

doi = "10.1051/0004-6361/202452611",

language = "English",

volume = "695",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

August, PC , Buchhave, LA , Diamond-Lowe, H , Mendonça, JM, Gressier, A, Rathcke, AD, Allen, NH, Fortune, M, Jones, KD, Meier Valdés, EA, Demory, BO, Espinoza, N, Fisher, CE, Gibson, NP, Heng, K, Hoeijmakers, J, Hooton, MJ, Kitzmann, D, Prinoth, B, Eastman, JD & Barnes, R 2025, 'Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b', Astronomy and Astrophysics, vol. 695, A171. https://doi.org/10.1051/0004-6361/202452611

TY - JOUR

T1 - Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b

AU - August, P. C.

AU - Buchhave, L. A.

AU - Diamond-Lowe, H.

AU - Mendonça, J. M.

AU - Gressier, A.

AU - Rathcke, A. D.

AU - Allen, N. H.

AU - Fortune, M.

AU - Jones, K. D.

AU - Meier Valdés, E. A.

AU - Demory, B. O.

AU - Espinoza, N.

AU - Fisher, C. E.

AU - Gibson, N. P.

AU - Heng, K.

AU - Hoeijmakers, J.

AU - Hooton, M. J.

AU - Kitzmann, D.

AU - Prinoth, B.

AU - Eastman, J. D.

AU - Barnes, R.

PY - 2025

Y1 - 2025

N2 - Context. M-dwarf systems offer an opportunity to study terrestrial exoplanetary atmospheres due to their small size and cool temperatures. However, the extreme conditions imposed by these host stars raise a question about whether their close-in rocky planets are able to retain any atmosphere at all. Aims. The Hot Rocks Survey aims to answer this question by targeting nine different M-dwarf rocky planets spanning a range of planetary and stellar properties. Of these, LHS 1478 b orbits an M3-type star, has an equilibrium temperature of Teq = 585 K, and receives 21 times Earth's instellation. Methods. We observed two secondary eclipses of LHS 1478 b using photometric imaging at 15 μm using the Mid-Infrared Instrument on the James Webb Space Telescope (JWST MIRI) to measure thermal emission from the dayside of the planet. We compared these values to atmospheric models to evaluate potential heat transport and CO2 absorption signatures. Results. We find that a secondary eclipse depth of 138 ± 53 ppm at the expected time for a circular orbit is preferred over a null model at 2.8σ, a moderate detection, though dynamical models do favour a non-eccentric orbit for this planet. The second observation results in a non-detection due to significantly larger unexplained systematics. Based on the first observation alone, we can reject the null hypothesis of the dark (zero Bond albedo) no atmosphere bare rock model with a confidence level of 3.3σ, though for AB = 0.2 the significance decreases to 2.1σ. The tentative secondary eclipse depth is consistent with the majority of the atmospheric scenarios we considered, spanning CO2-rich atmospheres with surface pressures from 0.1 to 10 bar. However, we stress that the two observations from our programme do not yield consistent results, and more observations are needed to verify our findings. The Hot Rocks Survey serves as a relevant primer for future endeavours such as the Director's Discretionary Time (DDT) Rocky Worlds programme.

AB - Context. M-dwarf systems offer an opportunity to study terrestrial exoplanetary atmospheres due to their small size and cool temperatures. However, the extreme conditions imposed by these host stars raise a question about whether their close-in rocky planets are able to retain any atmosphere at all. Aims. The Hot Rocks Survey aims to answer this question by targeting nine different M-dwarf rocky planets spanning a range of planetary and stellar properties. Of these, LHS 1478 b orbits an M3-type star, has an equilibrium temperature of Teq = 585 K, and receives 21 times Earth's instellation. Methods. We observed two secondary eclipses of LHS 1478 b using photometric imaging at 15 μm using the Mid-Infrared Instrument on the James Webb Space Telescope (JWST MIRI) to measure thermal emission from the dayside of the planet. We compared these values to atmospheric models to evaluate potential heat transport and CO2 absorption signatures. Results. We find that a secondary eclipse depth of 138 ± 53 ppm at the expected time for a circular orbit is preferred over a null model at 2.8σ, a moderate detection, though dynamical models do favour a non-eccentric orbit for this planet. The second observation results in a non-detection due to significantly larger unexplained systematics. Based on the first observation alone, we can reject the null hypothesis of the dark (zero Bond albedo) no atmosphere bare rock model with a confidence level of 3.3σ, though for AB = 0.2 the significance decreases to 2.1σ. The tentative secondary eclipse depth is consistent with the majority of the atmospheric scenarios we considered, spanning CO2-rich atmospheres with surface pressures from 0.1 to 10 bar. However, we stress that the two observations from our programme do not yield consistent results, and more observations are needed to verify our findings. The Hot Rocks Survey serves as a relevant primer for future endeavours such as the Director's Discretionary Time (DDT) Rocky Worlds programme.

KW - Planets and satellites: atmospheres

KW - Planets and satellites: terrestrial planets

KW - Techniques: photometric

U2 - 10.1051/0004-6361/202452611

DO - 10.1051/0004-6361/202452611

M3 - Journal article

SN - 0004-6361

VL - 695

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A171

ER -

Hot Rocks Survey I: A possible shallow eclipse for LHS 1478 b

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