Zooming in on the formation of protoplanetary disks

Research output: Contribution to journalJournal articleResearchpeer-review

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Zooming in on the formation of protoplanetary disks. / Nordlund, Åke; Haugbølle, Troels; Küffmeier, Michael; Paodoan, Paolo; Vasileiades, Aris.

In: Proceedings of the International Astronomical Union, Vol. 8, No. 299, 06.01.2014, p. 131-135.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Nordlund, Å, Haugbølle, T, Küffmeier, M, Paodoan, P & Vasileiades, A 2014, 'Zooming in on the formation of protoplanetary disks', Proceedings of the International Astronomical Union, vol. 8, no. 299, pp. 131-135. https://doi.org/10.1017/S1743921313008107

APA

Nordlund, Å., Haugbølle, T., Küffmeier, M., Paodoan, P., & Vasileiades, A. (2014). Zooming in on the formation of protoplanetary disks. Proceedings of the International Astronomical Union, 8(299), 131-135. https://doi.org/10.1017/S1743921313008107

Vancouver

Nordlund Å, Haugbølle T, Küffmeier M, Paodoan P, Vasileiades A. Zooming in on the formation of protoplanetary disks. Proceedings of the International Astronomical Union. 2014 Jan 6;8(299):131-135. https://doi.org/10.1017/S1743921313008107

Author

Nordlund, Åke ; Haugbølle, Troels ; Küffmeier, Michael ; Paodoan, Paolo ; Vasileiades, Aris. / Zooming in on the formation of protoplanetary disks. In: Proceedings of the International Astronomical Union. 2014 ; Vol. 8, No. 299. pp. 131-135.

Bibtex

@article{0fb330d25fd44d82bcac07ae188d7905,
title = "Zooming in on the formation of protoplanetary disks",
abstract = "We use the adaptive mesh refinement code RAMSES to model the formation of protoplanetary disks in realistic star formation environments. The resolution scales over up to 29 powers of two ($\sim$ 9 orders of magnitude) covering a range from outer scales of 40 pc to inner scales of 0.015 AU. The accretion rate from a 1.5 solar mass envelope peaks near $10^{-4}$ $\mspy$ about 6 kyr after sink particle formation and then decays approximately exponentially, reaching $10^{-6}$ $\mspy$ in 100 kyr. The models suggest universal scalings of physical properties with radius during the main accretion phase, with kinetic and / or magnetic energy in approximate balance with gravitational energy. Efficient accretion is made possible by the braking action of the magnetic field, which nevertheless allows a near-Keplerian disk to grow to a 100 AU size. The magnetic field strength ranges from more than 10 G at 0.1 AU to less than 1 mG at 100 AU, and drives a time dependent bipolar outflow, with a collimated jet and a broader disk wind.",
keywords = "astro-ph.SR",
author = "{\AA}ke Nordlund and Troels Haugb{\o}lle and Michael K{\"u}ffmeier and Paolo Paodoan and Aris Vasileiades",
year = "2014",
month = jan,
day = "6",
doi = "10.1017/S1743921313008107",
language = "English",
volume = "8",
pages = "131--135",
journal = "Proceedings of the International Astronomical Union",
issn = "1743-9213",
publisher = "Cambridge University Press",
number = "299",

}

RIS

TY - JOUR

T1 - Zooming in on the formation of protoplanetary disks

AU - Nordlund, Åke

AU - Haugbølle, Troels

AU - Küffmeier, Michael

AU - Paodoan, Paolo

AU - Vasileiades, Aris

PY - 2014/1/6

Y1 - 2014/1/6

N2 - We use the adaptive mesh refinement code RAMSES to model the formation of protoplanetary disks in realistic star formation environments. The resolution scales over up to 29 powers of two ($\sim$ 9 orders of magnitude) covering a range from outer scales of 40 pc to inner scales of 0.015 AU. The accretion rate from a 1.5 solar mass envelope peaks near $10^{-4}$ $\mspy$ about 6 kyr after sink particle formation and then decays approximately exponentially, reaching $10^{-6}$ $\mspy$ in 100 kyr. The models suggest universal scalings of physical properties with radius during the main accretion phase, with kinetic and / or magnetic energy in approximate balance with gravitational energy. Efficient accretion is made possible by the braking action of the magnetic field, which nevertheless allows a near-Keplerian disk to grow to a 100 AU size. The magnetic field strength ranges from more than 10 G at 0.1 AU to less than 1 mG at 100 AU, and drives a time dependent bipolar outflow, with a collimated jet and a broader disk wind.

AB - We use the adaptive mesh refinement code RAMSES to model the formation of protoplanetary disks in realistic star formation environments. The resolution scales over up to 29 powers of two ($\sim$ 9 orders of magnitude) covering a range from outer scales of 40 pc to inner scales of 0.015 AU. The accretion rate from a 1.5 solar mass envelope peaks near $10^{-4}$ $\mspy$ about 6 kyr after sink particle formation and then decays approximately exponentially, reaching $10^{-6}$ $\mspy$ in 100 kyr. The models suggest universal scalings of physical properties with radius during the main accretion phase, with kinetic and / or magnetic energy in approximate balance with gravitational energy. Efficient accretion is made possible by the braking action of the magnetic field, which nevertheless allows a near-Keplerian disk to grow to a 100 AU size. The magnetic field strength ranges from more than 10 G at 0.1 AU to less than 1 mG at 100 AU, and drives a time dependent bipolar outflow, with a collimated jet and a broader disk wind.

KW - astro-ph.SR

U2 - 10.1017/S1743921313008107

DO - 10.1017/S1743921313008107

M3 - Journal article

VL - 8

SP - 131

EP - 135

JO - Proceedings of the International Astronomical Union

JF - Proceedings of the International Astronomical Union

SN - 1743-9213

IS - 299

ER -

ID: 50621606