Hecuba-gap asteroid (original) (raw)
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A Hecuba-gap asteroid is a member of a dynamical group of resonant asteroids located in the Hecuba gap at 3.27 AU – one of the largest Kirkwood gaps in the asteroid belt, which is considered the borderline separating the outer main belt asteroids from the Cybeles. A Hecuba-gap asteroid stays in a 2:1 mean motion resonance with the gas giant Jupiter, which may gradually perturbe its orbits over a long period until it either intersect with the orbit of Mars or Jupiter itself. Depending on the dynamical stability of an asteroid's orbit in the Hecuba gap, three subgroups have been proposed. These are the marginally unstable Griqua asteroids, with an estimated lifetime of more than 100 million years, the stable Zhongguo asteroids (more than 500 million or even 1 billion years), and an unnamed, strongly unstable population of asteroids with a dynamical lifetime of less than 70 million years.[1][2][3]
Moving further out the Solar System, the asteroids in the Hecuba gap are followed by the resonant Cybeles (7:4), Hildas (3:2), Thules (4:3) and Jupiter trojans (1:1).
Both the Zhongguo (stable) and Griqua asteroids (marginally stable) are also described as the "long-lived" group with lifetimes over 70 million years in order to distinct them from the "short-lived" population. The division between the Griquas and Zhongguo into clearly distinct groups in terms of lifetime has also been questioned and follow-up studies have moved the threshold lifetime between the two long-lived groups from 500 million to 1 billion years.[2]
The Griqua asteroids (also known as the "Griquas") are a dynamical group of asteroids with marginally unstable orbits. The group derives its name from the asteroid 1362 Griqua. The Griquas are located in the Hecuba gap – one of the largest Kirkwood gaps in the asteroid belt at 3.27 AU – and stay in a 2:1 mean motion resonance with the gas giant Jupiter, which gradually perturbes their orbits over a long period until they either intersect with the orbit of Mars or Jupiter itself. The group has an estimated lifetime of 100 to (at least) 500 million years. Known members of the Griqua group include (articles in boldface):[1]: 422
- 1362 Griqua
- 3688 Navajo
- 4177 Kohman
- 11665 Dirichlet
- 13963 Euphrates
- (24491) 2000 YT123
- (28459) 2000 AW144
- (29524) 1998 AE
- (35989) 1999 NF10
- (86358) 1999 XB143
- (104742) 2000 HY9
While the Griquas are asteroids in a marginally unstable orbit, the Zhongguo asteroids (or "Zhongguos"; named after 3789 Zhongguo) are in a rather stable 1:2 resonance with Jupiter. The group of 26 identified members, with a lifetime of more than 530 million (or even 1 billion[2]) years, can be further divided into two clusters in the pseudo-proper element space:[1]: 423
- 3789 Zhongguo
- (11097) 1994 UD1
- 11266 Macke
- 11573 Helmholtz
- 14871 Pyramus
- (16882) 1998 BO13
- (18888) 2000 AV246
- 22740 Rayleigh
- (24514) 2001 BB58
- (26112) 1991 PG18
- 31249 Renéefleming
- (31293) 1998 FP70
- (36140) 1999 RC168
- (37528) 1975 SX
- (37991) 1998 KZ5
- (38984) 2000 UZ4
- (39018) 2000 UM53
- (41262) 1999 XZ55
- 45511 Anneblack
- (71694) 2000 FN44
- (86343) 1999 XZ56
- (91182) 1998 RO49
- (102915) 1999 XT23
- (130295) 2000 EF60
- (138739) 2000 SF206
- (146258) 2001 AO22
Strongly unstable group
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Related but distinct from the "long-lived" Griquas and Zhongguos, is the group of "unstable" Hecuba-gap asteroids:[1]: 422, 423
- 1921 Pala
- 1922 Zulu
- 5201 Ferraz-Mello
- 5370 Taranis (AMO)
- 8373 Stephengould
- 9767 Midsomer Norton
- (159367) 1977 OX
- (23577) 1995 DY8
- (26166) 1995 QN3 (AMO)
- (31339) 1998 KY30
- (37237) 2000 WZ161
- 65541 Kasbek
- (86367) 1999 XY223
- (136620) 1994 JC
- (252002) 2000 EU170
- (495832) 2000 JV60
In 2005, further research expanded this group of 16 bodies with an additional 31 multi-opposition asteroids, that show life-times of less than 70 million years. It is also thought that approximately 25% of the short-lived population are "extremely unstable" with lifetimes of less than 2 million years.[2]
- (55068) 2001 QX83
- (57565) 2001 TB52
- (82009) 2000 RF68
- (83943) 2001 WK14
- (86358) 1999 XB143
- (95488) 2002 EV25
- (97653) 2000 FH13
- (108455) 2001 KD50
- (114721) 2003 GG32
- (114804) 2003 NS8
- (114926) 2003 QW42
- (115916) 2003 WB8
- (116908) 2004 GT2
- (121906) 2000 DB62
- (140348) 2001 TK15
- (162983) 2001 RP53
- (166564) 2002 RB107
- (182931) 2002 GQ1
- (184922) 2005 UP497
- (206310) 2003 HG38
- (222927) 2002 LN53
- (228994) 2003 WO87
- (257379) 2009 RP55
- (274786) 2008 VT75
- (307464) 2002 WL
- (376874) 2001 VE
- (405132) 2002 JH36
- (437994) 2003 UL12 (APO)
- (443805) 1997 WW
- (455157) 1997 YM3 (AMO)
- (506437) 2000 WL10 (APO)
Among the unstable population, some asteroids have such a high eccentricity with a perihelion of less than 1.3 AU, that qualifies them as a near-Earth object. These five bodies (with their current eccentricity taken from the JPL SBDB in parentheses) are 5370 Taranis (0.64), 1995 QN3 (0.65), 2003 UL12 (0.70), 1997 YM3 (0.66), 2000 WL10 (0.72).[2]
- ^ a b c d Roig, F.; Nesvorný, D.; Ferraz-Mello, S. (September 2002). "Asteroids in the 2 : 1 resonance with Jupiter: dynamics and size distribution [ Erratum: 2002MNRAS.336.1391R ]". Monthly Notices of the Royal Astronomical Society. 335 (2): 417–431. Bibcode:2002MNRAS.335..417R. doi:10.1046/j.1365-8711.2002.05635.x.
- ^ a b c d e Broz, M.; Vokrouhlický, D.; Roig, F.; Nesvorný, D.; Bottke, W. F.; Morbidelli, A. (June 2005). "Yarkovsky origin of the unstable asteroids in the 2/1 mean motion resonance with Jupiter". Monthly Notices of the Royal Astronomical Society. 359 (4): 1437–1455. Bibcode:2005MNRAS.359.1437B. doi:10.1111/j.1365-2966.2005.08995.x.
- ^ Chrenko, O.; Broz, M.; Nesvorný, D.; Tsiganis, K.; Skoulidou, D. K. (August 2015). "The origin of long-lived asteroids in the 2:1 mean-motion resonance with Jupiter". Monthly Notices of the Royal Astronomical Society. 451 (3): 2399–2416. arXiv:1505.04329. Bibcode:2015MNRAS.451.2399C. doi:10.1093/mnras/stv1109.
- On the Origin of the Long-Lived Asteroids in the 2:1 Mean-Motion Resonance with Jupiter, 8-slide presentation, Chrenko, 2014
- Dynamics of the Solar System – Publication overview, Miroslav Broz, Institute of Astronomy, Charles University
- EasySky, orbital diagram
- Minor planet groups/families, www.projectpluto.com