ORBITAL SURVIVAL OF METER-SIZE AND LARGER BODIES DURING GRAVITATIONALLY UNSTABLE PHASES OF PROTOPLANETARY DISK EVOLUTION
ABSTRACT A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto the protostar as a result of gas drag forces. Such inward migration can be halted, and indeed even reversed, in a protoplanetary disk with lo...
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| Published in | The Astrophysical journal Vol. 807; no. 1; pp. 10 - 12 |
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| Main Author | |
| Format | Journal Article |
| Language | English |
| Published |
United Kingdom
The American Astronomical Society
01.07.2015
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0004-637X 1538-4357 1538-4357 |
| DOI | 10.1088/0004-637X/807/1/10 |
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| Abstract | ABSTRACT A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto the protostar as a result of gas drag forces. Such inward migration can be halted, and indeed even reversed, in a protoplanetary disk with local pressure maxima, such as marginally gravitationally unstable (MGU) phases of evolution, e.g., FU Orionis events. Results are presented for a suite of three-dimensional models of MGU disks extending from 1 to 10 AU and containing solid particles with sizes of 1 cm, 10 cm, 1 m, or 10 m, subject to disk gas drag and gravitational forces. These hydrodynamical models show that over disk evolution time scales of years or longer, during which over half the gaseous disk mass is accreted by the protostar, very few 1 and 10 m bodies are lost through inward migration: most bodies survive and orbit stably in the outer disk. A greater fraction of 1 and 10 cm particles are lost to the central protostar during these time periods, as such particles are more closely tied to the disk gas accreting onto the protostar, but even in these cases, a significant fraction survive and undergo transport from the hot inner disk to the cold outer disk, perhaps explaining the presence of small refractory particles in Comet Wild 2. Evidently MGU disk phases offer a means to overcome the m-sized migration barrier to collisional accumulation. |
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| AbstractList | A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto the protostar as a result of gas drag forces. Such inward migration can be halted, and indeed even reversed, in a protoplanetary disk with local pressure maxima, such as marginally gravitationally unstable (MGU) phases of evolution, e.g., FU Orionis events. Results are presented for a suite of three-dimensional models of MGU disks extending from 1 to 10 AU and containing solid particles with sizes of 1 cm, 10 cm, 1 m, or 10 m, subject to disk gas drag and gravitational forces. These hydrodynamical models show that over disk evolution time scales of ~6 x 10 super(3) years or longer, during which over half the gaseous disk mass is accreted by the protostar, very few 1 and 10 m bodies are lost through inward migration: most bodies survive and orbit stably in the outer disk. A greater fraction of 1 and 10 cm particles are lost to the central protostar during these time periods, as such particles are more closely tied to the disk gas accreting onto the protostar, but even in these cases, a significant fraction survive and undergo transport from the hot inner disk to the cold outer disk, perhaps explaining the presence of small refractory particles in Comet Wild 2. Evidently MGU disk phases offer a means to overcome the m-sized migration barrier to collisional accumulation. ABSTRACT A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto the protostar as a result of gas drag forces. Such inward migration can be halted, and indeed even reversed, in a protoplanetary disk with local pressure maxima, such as marginally gravitationally unstable (MGU) phases of evolution, e.g., FU Orionis events. Results are presented for a suite of three-dimensional models of MGU disks extending from 1 to 10 AU and containing solid particles with sizes of 1 cm, 10 cm, 1 m, or 10 m, subject to disk gas drag and gravitational forces. These hydrodynamical models show that over disk evolution time scales of years or longer, during which over half the gaseous disk mass is accreted by the protostar, very few 1 and 10 m bodies are lost through inward migration: most bodies survive and orbit stably in the outer disk. A greater fraction of 1 and 10 cm particles are lost to the central protostar during these time periods, as such particles are more closely tied to the disk gas accreting onto the protostar, but even in these cases, a significant fraction survive and undergo transport from the hot inner disk to the cold outer disk, perhaps explaining the presence of small refractory particles in Comet Wild 2. Evidently MGU disk phases offer a means to overcome the m-sized migration barrier to collisional accumulation. A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto the protostar as a result of gas drag forces. Such inward migration can be halted, and indeed even reversed, in a protoplanetary disk with local pressure maxima, such as marginally gravitationally unstable (MGU) phases of evolution, e.g., FU Orionis events. Results are presented for a suite of three-dimensional models of MGU disks extending from 1 to 10 AU and containing solid particles with sizes of 1 cm, 10 cm, 1 m, or 10 m, subject to disk gas drag and gravitational forces. These hydrodynamical models show that over disk evolution time scales of ∼6×10{sup 3} years or longer, during which over half the gaseous disk mass is accreted by the protostar, very few 1 and 10 m bodies are lost through inward migration: most bodies survive and orbit stably in the outer disk. A greater fraction of 1 and 10 cm particles are lost to the central protostar during these time periods, as such particles are more closely tied to the disk gas accreting onto the protostar, but even in these cases, a significant fraction survive and undergo transport from the hot inner disk to the cold outer disk, perhaps explaining the presence of small refractory particles in Comet Wild 2. Evidently MGU disk phases offer a means to overcome the m-sized migration barrier to collisional accumulation. |
| Author | Boss, Alan P. |
| Author_xml | – sequence: 1 givenname: Alan P. surname: Boss fullname: Boss, Alan P. organization: Department of Terrestrial Magnetism, Carnegie Institution for Science, 5241 Broad Branch Road, NW, Washington, DC 20015-1305, USA |
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| References | 22 Boss A. P. (12) 2007; 660 Haghighipour N. (25) 2003; 598 26 27 28 29 Boley A. C. (5) 2010; 724 Simon J. B. (35) 2014; 784 Christiaens V. (21) 2014; 785 Boss A. P. (11) 2005; 629 Mann R. K. (30) 2015; 802 Zhu Z. (43) 2010; 713 31 10 32 33 34 13 Dipierro G. (23) 2015 36 Boley A. C. (6) 2014; 792 15 Bae J. (2) 2014; 795 16 17 39 18 Vorobyov E. I. (38) 2010; 714 19 Vorobyov E. I. (37) 2005; 633 Zhu Z. (44) 2015; 801 Haghighipour N. (24) 2003; 583 Chambers J. E. (20) 2003; 126 1 3 4 7 8 9 Weidenschilling S. J. ed Kerridge J. F. (41) 1988 40 Boss A. P. (14) 2012; 764 42 |
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| Snippet | ABSTRACT A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto... A long-standing problem in the collisional accretion of terrestrial planets is the possible loss of m-size bodies through their inward migration onto the... |
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| SubjectTerms | Accretion disks ASTROPHYSICS, COSMOLOGY AND ASTRONOMY COMETS Disks Drag Evolution GRAVITATION HYDRODYNAMICS instabilities MASS Migration ORBITS Phases Planet formation PLANETS planets and satellites: formation protoplanetary disks PROTOPLANETS PROTOSTARS REFRACTORIES SATELLITES THREE-DIMENSIONAL CALCULATIONS |
| Title | ORBITAL SURVIVAL OF METER-SIZE AND LARGER BODIES DURING GRAVITATIONALLY UNSTABLE PHASES OF PROTOPLANETARY DISK EVOLUTION |
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