Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system

K. K.W. Hoch; M. Rowland; S. Petrus; E. Nasedkin; C. Ingebretsen; J. Kammerer; M. Perrin; V. D’Orazi; W. O. Balmer; T. Barman; M. Bonnefoy; G. Chauvin; C. Chen; R. J. De Rosa; J. Girard; E. Gonzales; M. Kenworthy; Q. M. Konopacky; B. Macintosh; S. E. Moran; C. V. Morley; P. Palma-Bifani; L. Pueyo; B. Ren; E. Rickman; J. B. Ruffio; C. A. Theissen; K. Ward-Duong; Y. Zhang

doi:10.1038/s41586-025-09174-w

Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system

K. K.W. Hoch
, M. Rowland
, S. Petrus
, E. Nasedkin
, C. Ingebretsen
, J. Kammerer
, M. Perrin
, V. D’Orazi
, W. O. Balmer
, T. Barman
, M. Bonnefoy
, G. Chauvin
, C. Chen
, R. J. De Rosa
, J. Girard
, E. Gonzales
, M. Kenworthy
, Q. M. Konopacky
, B. Macintosh
, S. E. Moran

C. V. Morley, P. Palma-Bifani, L. Pueyo, B. Ren, E. Rickman, J. B. Ruffio, C. A. Theissen, K. Ward-Duong, Y. Zhang

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

6 Scopus citations

Abstract

Young exoplanets provide an important link between understanding planet formation and atmospheric evolution¹. Direct imaging spectroscopy allows us to infer the properties of young, wide-orbit, giant planets with high signal-to-noise ratio. This allows us to compare this young population with exoplanets characterized by transmission spectroscopy, which has indirectly revealed the presence of clouds^{2, 3–4}, photochemistry⁵ and a diversity of atmospheric compositions^6,7. Direct detections have also been made for brown dwarfs^8,9, but direct studies of young giant planets in the mid-infrared were not possible before James Webb Space Telescope¹⁰. With two exoplanets around a solar-type star, the YSES-1 system is an ideal laboratory for studying this early phase of exoplanet evolution. Here we report the direct observations of silicate clouds in the atmosphere of the exoplanet YSES-1 c through its 9–11 µm absorption feature, and the first circumplanetary disk silicate emission around its sibling planet, YSES-1 b. The clouds of YSES-1 c are composed of either amorphous iron-enriched pyroxene or a combination of amorphous MgSiO₃ and Mg₂SiO₄, with particle sizes of ≤0.1 μm at 1 millibar pressure. We attribute the emission from the disk around YSES-1 b to be from submicron olivine dust grains, which may have formed through collisions of planet-forming bodies in the disk.

Original language	English (US)
Pages (from-to)	938-942
Number of pages	5
Journal	Nature
Volume	643
Issue number	8073
DOIs	https://doi.org/10.1038/s41586-025-09174-w
State	Published - Jul 24 2025

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Hoch, K. K. W., Rowland, M., Petrus, S., Nasedkin, E., Ingebretsen, C., Kammerer, J., Perrin, M., D’Orazi, V., Balmer, W. O., Barman, T., Bonnefoy, M., Chauvin, G., Chen, C., De Rosa, R. J., Girard, J., Gonzales, E., Kenworthy, M., Konopacky, Q. M., Macintosh, B., ... Zhang, Y. (2025). Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system. Nature, 643(8073), 938-942. https://doi.org/10.1038/s41586-025-09174-w

Hoch, KKW, Rowland, M, Petrus, S, Nasedkin, E, Ingebretsen, C, Kammerer, J, Perrin, M, D’Orazi, V, Balmer, WO, Barman, T, Bonnefoy, M, Chauvin, G, Chen, C, De Rosa, RJ, Girard, J, Gonzales, E, Kenworthy, M, Konopacky, QM, Macintosh, B, Moran, SE, Morley, CV, Palma-Bifani, P, Pueyo, L, Ren, B, Rickman, E, Ruffio, JB, Theissen, CA, Ward-Duong, K & Zhang, Y 2025, 'Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system', Nature, vol. 643, no. 8073, pp. 938-942. https://doi.org/10.1038/s41586-025-09174-w

@article{20356a8cf31444a8a8db36837f680673,

title = "Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system",

abstract = "Young exoplanets provide an important link between understanding planet formation and atmospheric evolution1. Direct imaging spectroscopy allows us to infer the properties of young, wide-orbit, giant planets with high signal-to-noise ratio. This allows us to compare this young population with exoplanets characterized by transmission spectroscopy, which has indirectly revealed the presence of clouds2, 3–4, photochemistry5 and a diversity of atmospheric compositions6,7. Direct detections have also been made for brown dwarfs8,9, but direct studies of young giant planets in the mid-infrared were not possible before James Webb Space Telescope10. With two exoplanets around a solar-type star, the YSES-1 system is an ideal laboratory for studying this early phase of exoplanet evolution. Here we report the direct observations of silicate clouds in the atmosphere of the exoplanet YSES-1 c through its 9–11 µm absorption feature, and the first circumplanetary disk silicate emission around its sibling planet, YSES-1 b. The clouds of YSES-1 c are composed of either amorphous iron-enriched pyroxene or a combination of amorphous MgSiO3 and Mg2SiO4, with particle sizes of ≤0.1 μm at 1 millibar pressure. We attribute the emission from the disk around YSES-1 b to be from submicron olivine dust grains, which may have formed through collisions of planet-forming bodies in the disk.",

author = "Hoch, \{K. K.W.\} and M. Rowland and S. Petrus and E. Nasedkin and C. Ingebretsen and J. Kammerer and M. Perrin and V. D{\textquoteright}Orazi and Balmer, \{W. O.\} and T. Barman and M. Bonnefoy and G. Chauvin and C. Chen and \{De Rosa\}, \{R. J.\} and J. Girard and E. Gonzales and M. Kenworthy and Konopacky, \{Q. M.\} and B. Macintosh and Moran, \{S. E.\} and Morley, \{C. V.\} and P. Palma-Bifani and L. Pueyo and B. Ren and E. Rickman and Ruffio, \{J. B.\} and Theissen, \{C. A.\} and K. Ward-Duong and Y. Zhang",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

year = "2025",

month = jul,

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doi = "10.1038/s41586-025-09174-w",

language = "English (US)",

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pages = "938--942",

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T1 - Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system

AU - Hoch, K. K.W.

AU - Rowland, M.

AU - Petrus, S.

AU - Nasedkin, E.

AU - Ingebretsen, C.

AU - Kammerer, J.

AU - Perrin, M.

AU - D’Orazi, V.

AU - Balmer, W. O.

AU - Barman, T.

AU - Bonnefoy, M.

AU - Chauvin, G.

AU - Chen, C.

AU - De Rosa, R. J.

AU - Girard, J.

AU - Gonzales, E.

AU - Kenworthy, M.

AU - Konopacky, Q. M.

AU - Macintosh, B.

AU - Moran, S. E.

AU - Morley, C. V.

AU - Palma-Bifani, P.

AU - Pueyo, L.

AU - Ren, B.

AU - Rickman, E.

AU - Ruffio, J. B.

AU - Theissen, C. A.

AU - Ward-Duong, K.

AU - Zhang, Y.

PY - 2025/7/24

Y1 - 2025/7/24

N2 - Young exoplanets provide an important link between understanding planet formation and atmospheric evolution1. Direct imaging spectroscopy allows us to infer the properties of young, wide-orbit, giant planets with high signal-to-noise ratio. This allows us to compare this young population with exoplanets characterized by transmission spectroscopy, which has indirectly revealed the presence of clouds2, 3–4, photochemistry5 and a diversity of atmospheric compositions6,7. Direct detections have also been made for brown dwarfs8,9, but direct studies of young giant planets in the mid-infrared were not possible before James Webb Space Telescope10. With two exoplanets around a solar-type star, the YSES-1 system is an ideal laboratory for studying this early phase of exoplanet evolution. Here we report the direct observations of silicate clouds in the atmosphere of the exoplanet YSES-1 c through its 9–11 µm absorption feature, and the first circumplanetary disk silicate emission around its sibling planet, YSES-1 b. The clouds of YSES-1 c are composed of either amorphous iron-enriched pyroxene or a combination of amorphous MgSiO3 and Mg2SiO4, with particle sizes of ≤0.1 μm at 1 millibar pressure. We attribute the emission from the disk around YSES-1 b to be from submicron olivine dust grains, which may have formed through collisions of planet-forming bodies in the disk.

AB - Young exoplanets provide an important link between understanding planet formation and atmospheric evolution1. Direct imaging spectroscopy allows us to infer the properties of young, wide-orbit, giant planets with high signal-to-noise ratio. This allows us to compare this young population with exoplanets characterized by transmission spectroscopy, which has indirectly revealed the presence of clouds2, 3–4, photochemistry5 and a diversity of atmospheric compositions6,7. Direct detections have also been made for brown dwarfs8,9, but direct studies of young giant planets in the mid-infrared were not possible before James Webb Space Telescope10. With two exoplanets around a solar-type star, the YSES-1 system is an ideal laboratory for studying this early phase of exoplanet evolution. Here we report the direct observations of silicate clouds in the atmosphere of the exoplanet YSES-1 c through its 9–11 µm absorption feature, and the first circumplanetary disk silicate emission around its sibling planet, YSES-1 b. The clouds of YSES-1 c are composed of either amorphous iron-enriched pyroxene or a combination of amorphous MgSiO3 and Mg2SiO4, with particle sizes of ≤0.1 μm at 1 millibar pressure. We attribute the emission from the disk around YSES-1 b to be from submicron olivine dust grains, which may have formed through collisions of planet-forming bodies in the disk.

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U2 - 10.1038/s41586-025-09174-w

DO - 10.1038/s41586-025-09174-w

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C2 - 40494394

AN - SCOPUS:105010777462

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VL - 643

SP - 938

EP - 942

JO - Nature

JF - Nature

IS - 8073

ER -

Silicate clouds and a circumplanetary disk in the YSES-1 exoplanet system

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