A planetary collision afterglow and transit of the resultant debris cloud

Matthew Kenworthy; Simon Lock; Grant Kennedy; Richelle van Capelleveen; Eric Mamajek; Ludmila Carone; Franz Josef Hambsch; Joseph Masiero; Amy Mainzer; J. Davy Kirkpatrick; Edward Gomez; Zoë Leinhardt; Jingyao Dou; Pavan Tanna; Arttu Sainio; Hamish Barker; Stéphane Charbonnel; Olivier Garde; Pascal Le Dû; Lionel Mulato; Thomas Petit; Michael Rizzo Smith

doi:10.1038/s41586-023-06573-9

A planetary collision afterglow and transit of the resultant debris cloud

Matthew Kenworthy, Simon Lock, Grant Kennedy, Richelle van Capelleveen, Eric Mamajek, Ludmila Carone, Franz Josef Hambsch, Joseph Masiero, Amy Mainzer, J. Davy Kirkpatrick, Edward Gomez, Zoë Leinhardt, Jingyao Dou, Pavan Tanna, Arttu Sainio, Hamish Barker, Stéphane Charbonnel, Olivier Garde, Pascal Le Dû, Lionel MulatoThomas Petit, Michael Rizzo Smith

Planetary Sciences

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

6 Scopus citations

Abstract

Planets grow in rotating disks of dust and gas around forming stars, some of which can subsequently collide in giant impacts after the gas component is removed from the disk^1–3. Monitoring programmes with the warm Spitzer mission have recorded substantial and rapid changes in mid-infrared output for several stars, interpreted as variations in the surface area of warm, dusty material ejected by planetary-scale collisions and heated by the central star: for example, NGC 2354–ID8 (refs. ^4,5), HD 166191 (ref. ⁶) and V488 Persei⁷. Here we report combined observations of the young (about 300 million years old), solar-like star ASASSN-21qj: an infrared brightening consistent with a blackbody temperature of 1,000 Kelvin and a luminosity that is 4 percent that of the star lasting for about 1,000 days, partially overlapping in time with a complex and deep, wavelength-dependent optical eclipse that lasted for about 500 days. The optical eclipse started 2.5 years after the infrared brightening, implying an orbital period of at least that duration. These observations are consistent with a collision between two exoplanets of several to tens of Earth masses at 2–16 astronomical units from the central star. Such an impact produces a hot, highly extended post-impact remnant with sufficient luminosity to explain the infrared observations. Transit of the impact debris, sheared by orbital motion into a long cloud, causes the subsequent complex eclipse of the host star.

Original language	English (US)
Pages (from-to)	251-254
Number of pages	4
Journal	Nature
Volume	622
Issue number	7982
DOIs	https://doi.org/10.1038/s41586-023-06573-9
State	Published - Oct 12 2023

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Kenworthy, M., Lock, S., Kennedy, G., van Capelleveen, R., Mamajek, E., Carone, L., Hambsch, F. J., Masiero, J., Mainzer, A., Kirkpatrick, J. D., Gomez, E., Leinhardt, Z., Dou, J., Tanna, P., Sainio, A., Barker, H., Charbonnel, S., Garde, O., Le Dû, P., ... Rizzo Smith, M. (2023). A planetary collision afterglow and transit of the resultant debris cloud. Nature, 622(7982), 251-254. https://doi.org/10.1038/s41586-023-06573-9

Kenworthy, M, Lock, S, Kennedy, G, van Capelleveen, R, Mamajek, E, Carone, L, Hambsch, FJ, Masiero, J, Mainzer, A, Kirkpatrick, JD, Gomez, E, Leinhardt, Z, Dou, J, Tanna, P, Sainio, A, Barker, H, Charbonnel, S, Garde, O, Le Dû, P, Mulato, L, Petit, T & Rizzo Smith, M 2023, 'A planetary collision afterglow and transit of the resultant debris cloud', Nature, vol. 622, no. 7982, pp. 251-254. https://doi.org/10.1038/s41586-023-06573-9

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title = "A planetary collision afterglow and transit of the resultant debris cloud",

abstract = "Planets grow in rotating disks of dust and gas around forming stars, some of which can subsequently collide in giant impacts after the gas component is removed from the disk1–3. Monitoring programmes with the warm Spitzer mission have recorded substantial and rapid changes in mid-infrared output for several stars, interpreted as variations in the surface area of warm, dusty material ejected by planetary-scale collisions and heated by the central star: for example, NGC 2354–ID8 (refs. 4,5), HD 166191 (ref. 6) and V488 Persei7. Here we report combined observations of the young (about 300 million years old), solar-like star ASASSN-21qj: an infrared brightening consistent with a blackbody temperature of 1,000 Kelvin and a luminosity that is 4 percent that of the star lasting for about 1,000 days, partially overlapping in time with a complex and deep, wavelength-dependent optical eclipse that lasted for about 500 days. The optical eclipse started 2.5 years after the infrared brightening, implying an orbital period of at least that duration. These observations are consistent with a collision between two exoplanets of several to tens of Earth masses at 2–16 astronomical units from the central star. Such an impact produces a hot, highly extended post-impact remnant with sufficient luminosity to explain the infrared observations. Transit of the impact debris, sheared by orbital motion into a long cloud, causes the subsequent complex eclipse of the host star.",

author = "Matthew Kenworthy and Simon Lock and Grant Kennedy and {van Capelleveen}, Richelle and Eric Mamajek and Ludmila Carone and Hambsch, {Franz Josef} and Joseph Masiero and Amy Mainzer and Kirkpatrick, {J. Davy} and Edward Gomez and Zo{\"e} Leinhardt and Jingyao Dou and Pavan Tanna and Arttu Sainio and Hamish Barker and St{\'e}phane Charbonnel and Olivier Garde and {Le D{\^u}}, Pascal and Lionel Mulato and Thomas Petit and {Rizzo Smith}, Michael",

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doi = "10.1038/s41586-023-06573-9",

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T1 - A planetary collision afterglow and transit of the resultant debris cloud

AU - Kenworthy, Matthew

AU - Lock, Simon

AU - Kennedy, Grant

AU - van Capelleveen, Richelle

AU - Mamajek, Eric

AU - Carone, Ludmila

AU - Hambsch, Franz Josef

AU - Masiero, Joseph

AU - Mainzer, Amy

AU - Kirkpatrick, J. Davy

AU - Gomez, Edward

AU - Leinhardt, Zoë

AU - Dou, Jingyao

AU - Tanna, Pavan

AU - Sainio, Arttu

AU - Barker, Hamish

AU - Charbonnel, Stéphane

AU - Garde, Olivier

AU - Le Dû, Pascal

AU - Mulato, Lionel

AU - Petit, Thomas

AU - Rizzo Smith, Michael

PY - 2023/10/12

Y1 - 2023/10/12

N2 - Planets grow in rotating disks of dust and gas around forming stars, some of which can subsequently collide in giant impacts after the gas component is removed from the disk1–3. Monitoring programmes with the warm Spitzer mission have recorded substantial and rapid changes in mid-infrared output for several stars, interpreted as variations in the surface area of warm, dusty material ejected by planetary-scale collisions and heated by the central star: for example, NGC 2354–ID8 (refs. 4,5), HD 166191 (ref. 6) and V488 Persei7. Here we report combined observations of the young (about 300 million years old), solar-like star ASASSN-21qj: an infrared brightening consistent with a blackbody temperature of 1,000 Kelvin and a luminosity that is 4 percent that of the star lasting for about 1,000 days, partially overlapping in time with a complex and deep, wavelength-dependent optical eclipse that lasted for about 500 days. The optical eclipse started 2.5 years after the infrared brightening, implying an orbital period of at least that duration. These observations are consistent with a collision between two exoplanets of several to tens of Earth masses at 2–16 astronomical units from the central star. Such an impact produces a hot, highly extended post-impact remnant with sufficient luminosity to explain the infrared observations. Transit of the impact debris, sheared by orbital motion into a long cloud, causes the subsequent complex eclipse of the host star.

AB - Planets grow in rotating disks of dust and gas around forming stars, some of which can subsequently collide in giant impacts after the gas component is removed from the disk1–3. Monitoring programmes with the warm Spitzer mission have recorded substantial and rapid changes in mid-infrared output for several stars, interpreted as variations in the surface area of warm, dusty material ejected by planetary-scale collisions and heated by the central star: for example, NGC 2354–ID8 (refs. 4,5), HD 166191 (ref. 6) and V488 Persei7. Here we report combined observations of the young (about 300 million years old), solar-like star ASASSN-21qj: an infrared brightening consistent with a blackbody temperature of 1,000 Kelvin and a luminosity that is 4 percent that of the star lasting for about 1,000 days, partially overlapping in time with a complex and deep, wavelength-dependent optical eclipse that lasted for about 500 days. The optical eclipse started 2.5 years after the infrared brightening, implying an orbital period of at least that duration. These observations are consistent with a collision between two exoplanets of several to tens of Earth masses at 2–16 astronomical units from the central star. Such an impact produces a hot, highly extended post-impact remnant with sufficient luminosity to explain the infrared observations. Transit of the impact debris, sheared by orbital motion into a long cloud, causes the subsequent complex eclipse of the host star.

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JO - Nature

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IS - 7982

ER -

A planetary collision afterglow and transit of the resultant debris cloud

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