Discovery of Volatile Gas in the Giant Impact Disk Around the 150 Myr Old HD 23514

Kate Y.L. Su; Attila Moór; Chengyan Xie; Ilaria Pascucci; George H. Rieke; Ágnes Kóspál; Mark C. Wyatt; Péter Ábrahám; Luca Matrà; Zoe Roumeliotis; D. J. Wilner

doi:10.3847/2041-8213/ade872

Discovery of Volatile Gas in the Giant Impact Disk Around the 150 Myr Old HD 23514

Kate Y.L. Su
, Attila Moór
, Chengyan Xie
, Ilaria Pascucci
, George H. Rieke
, Ágnes Kóspál
, Mark C. Wyatt
, Péter Ábrahám
, Luca Matrà
, Zoe Roumeliotis
, D. J. Wilner

Department of Astrophysics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

We report the discovery of CO₂ gas emission around HD 23514, an F5V star in the ∼150 Myr old Pleiades cluster, hosting one of the rare giant-impact disks with unique mineralogy dominated by silica dust. We show that the dust feature remains stable over several decades, and that the submicron grains, which give rise to the ∼9 μm feature, are cospatial with the hot CO₂ molecules within the sub-astronomical-unit vicinity of the star. Examining a Spitzer spectrum taken 15 yr earlier, we show that the CO₂ emission was also present at 4.3σ significance. The existence of tiny silica grains and volatile gas requires special conditions to prevent the rapid loss caused by stellar radiation pressure and photodissociation. We explore several pathways explaining the observed properties and suggest that a past giant impact and/or stripping atmospheric event, involving large bodies with volatile content similar to carbonaceous chondritic material, can simultaneously explain both the silica and volatile emission. Our discovery provides an important context for the amount of volatiles that a newly formed planet or the largest planetesimals could retain during the giant impact phase in the early solar system evolution.

Original language	English
Article number	L2
Number of pages	17
Journal	Astrophysical Journal Letters
Volume	988
Issue number	1
DOIs	https://doi.org/10.3847/2041-8213/ade872
Publication status	Published - 11 Jul 2025

Funding

This research has made use of the NASA/IPAC Infrared Science Archive, which is funded by the National Aeronautics and Space Administration and operated by the California Institute of Technology. Work on this paper was supported by grant 80NSSC18K0555 from the NASA Goddard Space Flight Center to the University of Arizona, and by 80NSSC20K1002 under the NASA ADAP program. A.M. is supported by the Hungarian National Research, Development and Innovation Office Élvonal grant KKP-143986. C.X. and I.P. acknowledge partial support by NASA STScI GO grant JWST-GO-02970.010. A.K. acknowledges the support of the NKFIH NKKP grant ADVANCED 149943 and the NKFIH excellence grant TKP2021-NKTA-64. Project no. 149943 has been implemented with the support provided by the Ministry of Culture and Innovation of Hungary from the National Research, Development and Innovation Fund, financed under the NKKP ADVANCED funding scheme. P.A. is partially supported by the Hungarian NKFIH grant K-147380. L.M and Z.R. acknowledge funding by the European Union through the E-BEANS ERC project (grant number 100117693). Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Research Council Executive Agency. Neither the European Union nor the granting authority can be held responsible for them.

Austrian Fields of Science 2012

103003 Astronomy
103004 Astrophysics

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title = "Discovery of Volatile Gas in the Giant Impact Disk Around the 150 Myr Old HD 23514",

abstract = "We report the discovery of CO2 gas emission around HD 23514, an F5V star in the ∼150 Myr old Pleiades cluster, hosting one of the rare giant-impact disks with unique mineralogy dominated by silica dust. We show that the dust feature remains stable over several decades, and that the submicron grains, which give rise to the ∼9 μm feature, are cospatial with the hot CO2 molecules within the sub-astronomical-unit vicinity of the star. Examining a Spitzer spectrum taken 15 yr earlier, we show that the CO2 emission was also present at 4.3σ significance. The existence of tiny silica grains and volatile gas requires special conditions to prevent the rapid loss caused by stellar radiation pressure and photodissociation. We explore several pathways explaining the observed properties and suggest that a past giant impact and/or stripping atmospheric event, involving large bodies with volatile content similar to carbonaceous chondritic material, can simultaneously explain both the silica and volatile emission. Our discovery provides an important context for the amount of volatiles that a newly formed planet or the largest planetesimals could retain during the giant impact phase in the early solar system evolution.",

author = "Su, \{Kate Y.L.\} and Attila Mo{\'o}r and Chengyan Xie and Ilaria Pascucci and Rieke, \{George H.\} and {\'A}gnes K{\'o}sp{\'a}l and Wyatt, \{Mark C.\} and P{\'e}ter {\'A}brah{\'a}m and Luca Matr{\`a} and Zoe Roumeliotis and Wilner, \{D. J.\}",

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AU - Su, Kate Y.L.

AU - Moór, Attila

AU - Xie, Chengyan

AU - Pascucci, Ilaria

AU - Rieke, George H.

AU - Kóspál, Ágnes

AU - Wyatt, Mark C.

AU - Ábrahám, Péter

AU - Matrà, Luca

AU - Roumeliotis, Zoe

AU - Wilner, D. J.

PY - 2025/7/11

Y1 - 2025/7/11

N2 - We report the discovery of CO2 gas emission around HD 23514, an F5V star in the ∼150 Myr old Pleiades cluster, hosting one of the rare giant-impact disks with unique mineralogy dominated by silica dust. We show that the dust feature remains stable over several decades, and that the submicron grains, which give rise to the ∼9 μm feature, are cospatial with the hot CO2 molecules within the sub-astronomical-unit vicinity of the star. Examining a Spitzer spectrum taken 15 yr earlier, we show that the CO2 emission was also present at 4.3σ significance. The existence of tiny silica grains and volatile gas requires special conditions to prevent the rapid loss caused by stellar radiation pressure and photodissociation. We explore several pathways explaining the observed properties and suggest that a past giant impact and/or stripping atmospheric event, involving large bodies with volatile content similar to carbonaceous chondritic material, can simultaneously explain both the silica and volatile emission. Our discovery provides an important context for the amount of volatiles that a newly formed planet or the largest planetesimals could retain during the giant impact phase in the early solar system evolution.

AB - We report the discovery of CO2 gas emission around HD 23514, an F5V star in the ∼150 Myr old Pleiades cluster, hosting one of the rare giant-impact disks with unique mineralogy dominated by silica dust. We show that the dust feature remains stable over several decades, and that the submicron grains, which give rise to the ∼9 μm feature, are cospatial with the hot CO2 molecules within the sub-astronomical-unit vicinity of the star. Examining a Spitzer spectrum taken 15 yr earlier, we show that the CO2 emission was also present at 4.3σ significance. The existence of tiny silica grains and volatile gas requires special conditions to prevent the rapid loss caused by stellar radiation pressure and photodissociation. We explore several pathways explaining the observed properties and suggest that a past giant impact and/or stripping atmospheric event, involving large bodies with volatile content similar to carbonaceous chondritic material, can simultaneously explain both the silica and volatile emission. Our discovery provides an important context for the amount of volatiles that a newly formed planet or the largest planetesimals could retain during the giant impact phase in the early solar system evolution.

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UR - https://ui.adsabs.harvard.edu/abs/2025ApJ...988L...2S/abstract

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DO - 10.3847/2041-8213/ade872

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Discovery of Volatile Gas in the Giant Impact Disk Around the 150 Myr Old HD 23514

Abstract

Funding

Austrian Fields of Science 2012

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