Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line

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Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line. / Bitsch, Bertram; Raymond, Sean N.; Buchhave, Lars A.; Bello-Arufe, Aaron; Rathcke, Alexander D.; Schneider, Aaron David.

In: Astronomy & Astrophysics, Vol. 649, A5, 05.05.2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Bitsch, B, Raymond, SN, Buchhave, LA, Bello-Arufe, A, Rathcke, AD & Schneider, AD 2021, 'Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line', Astronomy & Astrophysics, vol. 649, A5. https://doi.org/10.1051/0004-6361/202140793

APA

Bitsch, B., Raymond, S. N., Buchhave, L. A., Bello-Arufe, A., Rathcke, A. D., & Schneider, A. D. (2021). Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line. Astronomy & Astrophysics, 649, [A5]. https://doi.org/10.1051/0004-6361/202140793

Vancouver

Bitsch B, Raymond SN, Buchhave LA, Bello-Arufe A, Rathcke AD, Schneider AD. Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line. Astronomy & Astrophysics. 2021 May 5;649. A5. https://doi.org/10.1051/0004-6361/202140793

Author

Bitsch, Bertram ; Raymond, Sean N. ; Buchhave, Lars A. ; Bello-Arufe, Aaron ; Rathcke, Alexander D. ; Schneider, Aaron David. / Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line. In: Astronomy & Astrophysics. 2021 ; Vol. 649.

Bibtex

@article{f761ff912c3543b997370dec490000ee,
title = "Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line",
abstract = "In the pebble accretion scenario, the pebbles that form planets drift inward from the outer disk regions, carrying water ice with them. At the water ice line, the water ice on the inward drifting pebbles evaporates and is released into the gas phase, resulting in water-rich gas and dry pebbles that move into the inner disk regions. Large planetary cores can block the inward drifting pebbles by forming a pressure bump outside their orbit in the protoplanetary disk. Depending on the relative position of a growing planetary core relative to the water ice line, water-rich pebbles might be blocked outside or inside the water ice line. Pebbles blocked outside the water ice line do not evaporate and thus do not release their water vapor into the gas phase, resulting in a dry inner disk, while pebbles blocked inside the water ice line release their water vapor into the gas phase, resulting in water vapor diffusing into the inner disk. As a consequence, close-in sub-Neptunes that accrete some gas from the disk should be dry or wet, respectively, if outer gas giants are outside or inside the water ice line, assuming that giant planets form fast, as has been suggested for Jupiter in our Solar System. Alternatively, a sub-Neptune could form outside the water ice line, accreting a large amount of icy pebbles and then migrating inward as a very wet sub-Neptune. We suggest that the water content of inner sub-Neptunes in systems with giant planets that can efficiently block the inward drifting pebbles could constrain the formation conditions of these systems, thus making these sub-Neptunes exciting targets for detailed characterization (e.g., with JWST, ELT, or ARIEL). In addition, the search for giant planets in systems with already characterized sub-Neptunes can be used to constrain the formation conditions of giant planets as well.",
keywords = "accretion, accretion disks, planets and satellites: formation, protoplanetary disks, planets and satellites: composition, SUPER-EARTH SYSTEMS, PROTOPLANETARY DISKS, PEBBLE-ISOLATION, GAS ACCRETION, SNOW LINE, MIGRATION, MASS, EVOLUTION, METALLICITY, COAGULATION",
author = "Bertram Bitsch and Raymond, {Sean N.} and Buchhave, {Lars A.} and Aaron Bello-Arufe and Rathcke, {Alexander D.} and Schneider, {Aaron David}",
year = "2021",
month = may,
day = "5",
doi = "10.1051/0004-6361/202140793",
language = "English",
volume = "649",
journal = "Astronomy & Astrophysics",
issn = "0004-6361",
publisher = "E D P Sciences",

}

RIS

TY - JOUR

T1 - Dry or water world? How the water contents of inner sub-Neptunes constrain giant planet formation and the location of the water ice line

AU - Bitsch, Bertram

AU - Raymond, Sean N.

AU - Buchhave, Lars A.

AU - Bello-Arufe, Aaron

AU - Rathcke, Alexander D.

AU - Schneider, Aaron David

PY - 2021/5/5

Y1 - 2021/5/5

N2 - In the pebble accretion scenario, the pebbles that form planets drift inward from the outer disk regions, carrying water ice with them. At the water ice line, the water ice on the inward drifting pebbles evaporates and is released into the gas phase, resulting in water-rich gas and dry pebbles that move into the inner disk regions. Large planetary cores can block the inward drifting pebbles by forming a pressure bump outside their orbit in the protoplanetary disk. Depending on the relative position of a growing planetary core relative to the water ice line, water-rich pebbles might be blocked outside or inside the water ice line. Pebbles blocked outside the water ice line do not evaporate and thus do not release their water vapor into the gas phase, resulting in a dry inner disk, while pebbles blocked inside the water ice line release their water vapor into the gas phase, resulting in water vapor diffusing into the inner disk. As a consequence, close-in sub-Neptunes that accrete some gas from the disk should be dry or wet, respectively, if outer gas giants are outside or inside the water ice line, assuming that giant planets form fast, as has been suggested for Jupiter in our Solar System. Alternatively, a sub-Neptune could form outside the water ice line, accreting a large amount of icy pebbles and then migrating inward as a very wet sub-Neptune. We suggest that the water content of inner sub-Neptunes in systems with giant planets that can efficiently block the inward drifting pebbles could constrain the formation conditions of these systems, thus making these sub-Neptunes exciting targets for detailed characterization (e.g., with JWST, ELT, or ARIEL). In addition, the search for giant planets in systems with already characterized sub-Neptunes can be used to constrain the formation conditions of giant planets as well.

AB - In the pebble accretion scenario, the pebbles that form planets drift inward from the outer disk regions, carrying water ice with them. At the water ice line, the water ice on the inward drifting pebbles evaporates and is released into the gas phase, resulting in water-rich gas and dry pebbles that move into the inner disk regions. Large planetary cores can block the inward drifting pebbles by forming a pressure bump outside their orbit in the protoplanetary disk. Depending on the relative position of a growing planetary core relative to the water ice line, water-rich pebbles might be blocked outside or inside the water ice line. Pebbles blocked outside the water ice line do not evaporate and thus do not release their water vapor into the gas phase, resulting in a dry inner disk, while pebbles blocked inside the water ice line release their water vapor into the gas phase, resulting in water vapor diffusing into the inner disk. As a consequence, close-in sub-Neptunes that accrete some gas from the disk should be dry or wet, respectively, if outer gas giants are outside or inside the water ice line, assuming that giant planets form fast, as has been suggested for Jupiter in our Solar System. Alternatively, a sub-Neptune could form outside the water ice line, accreting a large amount of icy pebbles and then migrating inward as a very wet sub-Neptune. We suggest that the water content of inner sub-Neptunes in systems with giant planets that can efficiently block the inward drifting pebbles could constrain the formation conditions of these systems, thus making these sub-Neptunes exciting targets for detailed characterization (e.g., with JWST, ELT, or ARIEL). In addition, the search for giant planets in systems with already characterized sub-Neptunes can be used to constrain the formation conditions of giant planets as well.

KW - accretion

KW - accretion disks

KW - planets and satellites: formation

KW - protoplanetary disks

KW - planets and satellites: composition

KW - SUPER-EARTH SYSTEMS

KW - PROTOPLANETARY DISKS

KW - PEBBLE-ISOLATION

KW - GAS ACCRETION

KW - SNOW LINE

KW - MIGRATION

KW - MASS

KW - EVOLUTION

KW - METALLICITY

KW - COAGULATION

U2 - 10.1051/0004-6361/202140793

DO - 10.1051/0004-6361/202140793

M3 - Journal article

VL - 649

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

SN - 0004-6361

M1 - A5

ER -

ID: 271821708