Asteroid family
An asteroid family is a population of asteroids that share similar proper orbital elements, such as semimajor axis, eccentricity, and orbital inclination. The members of the families are thought to be fragments of past asteroid collisions. An asteroid family is a more specific term than asteroid group whose members, while sharing some broad orbital characteristics, may be otherwise unrelated to each other.
General properties
Large prominent families contain several hundred recognized asteroids (and many more smaller objects which may be either not-yet-analyzed, or not-yet-discovered). Small, compact families may have only about ten identified members. About 33% to 35% of asteroids in the main belt are family members.
There are about 20 to 30 reliably recognized families, with several tens of less certain groupings. Most asteroid families are found in the main asteroid belt, although several family-like groups such as the Pallas family, Hungaria family, and the Phocaea family lie at smaller semi-major axis or larger inclination than the main belt.
One family has been identified associated with the dwarf planet Haumea.[1] Some studies have tried to find evidence of collisional families among the trojan asteroids, but at present the evidence is inconclusive.
Origin and evolution
The families are thought to form as a result of collisions between asteroids. In many or most cases the parent body was shattered, but there are also several families which resulted from a large cratering event which did not disrupt the parent body (e.g. the Vesta, Pallas, Hygiea, and Massalia families). Such cratering families typically consist of a single large body and a swarm of asteroids that are much smaller. Some families (e.g. the Flora family) have complex internal structures which are not satisfactorily explained at the moment, but may be due to several collisions in the same region at different times.
Due to the method of origin, all the members have closely matching compositions for most families. Notable exceptions are those families (such as the Vesta family) which formed from a large differentiated parent body.
Asteroid families are thought to have lifetimes of the order of a billion years, depending on various factors (e.g. smaller asteroids are lost faster). This is significantly shorter than the Solar System's age, so few if any are relics of the early Solar System. Decay of families occurs both because of slow dissipation of the orbits due to perturbations from Jupiter or other large bodies, and because of collisions between asteroids which grind them down to small bodies. Such small asteroids then become subject to perturbations such as the Yarkovsky effect that can push them towards orbital resonances with Jupiter over time. Once there, they are relatively rapidly ejected from the asteroid belt. Tentative age estimates have been obtained for some families, ranging from hundreds of millions of years to less than several million years as for the compact Karin family. Old families are thought to contain few small members, and this is the basis of the age determinations.
It is supposed that many very old families have lost all the smaller and medium-sized members, leaving only a few of the largest intact. A suggested example of such old family remains are the 9 Metis and 113 Amalthea pair. Further evidence for a large number of past families (now dispersed) comes from analysis of chemical ratios in iron meteorites. These show that there must have once been at least 50 to 100 parent bodies large enough to be differentiated, that have since been shattered to expose their cores and produce the actual meteorites (Kelley & Gaffey 2000).
Identification of members and interlopers
When the orbital elements of main belt asteroids are plotted (typically inclination vs. eccentricity, or vs. semi-major axis), a number of distinct concentrations are seen against the rather uniform background distribution of generic asteroids. These concentrations are the asteroid families. Interlopers are asteroids classified as family members based on their so-called proper orbital elements but having spectroscopic properties distinct from the bulk of the family, suggesting that they, contrary to the true family members, did not originate from the same parent object that once fragmented upon a collisional impact.
Description
Strictly speaking, families and their membership are identified by analysing the proper orbital elements rather than the current osculating orbital elements, which regularly fluctuate on timescales of tens of thousands of years. The proper elements are related constants of motion that remain almost constant for times of at least tens of millions of years, and perhaps longer.
The Japanese astronomer Kiyotsugu Hirayama (1874–1943) pioneered the estimation of proper elements for asteroids, and first identified several of the most prominent families in 1918. In his honor, asteroid families are sometimes called Hirayama families. This particularly applies to the five prominent groupings discovered by him.
Present day computer-assisted searches have identified several tens of asteroid families. The most prominent algorithms have been the Hierarchical Clustering Method (HCM) which looks for groupings with small nearest-neighbour distances in orbital element space, and the Wavelet Analysis Method (WAM) which builds a density-of-asteroids map in orbital element space, and looks for density peaks.
The boundaries of the families are somewhat vague because at the edges they blend into the background density of asteroids in the main belt. For this reason the number of members even among discovered asteroids is usually only known approximately, and membership is uncertain for asteroids near the edges.
Additionally, some interlopers from the heterogeneous background asteroid population are expected even in the central regions of a family. Since the true family members caused by the collision are expected to have similar compositions, most such interlopers can in principle be recognised by spectral properties which do not match those of the bulk of family members. A prominent example is 1 Ceres, the largest asteroid, which is an interloper in the family once named after it (the Ceres family, now the Gefion family).
Spectral characteristics can also be used to determine the membership (or otherwise) of asteroids in the outer regions of a family, as has been used e.g. for the Vesta family, whose members have an unusual composition.
Family types
As previously mentioned, families caused by an impact that did not disrupt the parent body but only ejected fragments are called cratering families. Other terminology has been used to distinguish various types of groups which are less distinct or less statistically certain from the most prominent "nominal families" (or clusters). The term cluster is also used to describe a small asteroid family, such as the Karin Cluster.[2] Clumps are groupings which have relatively few members but are clearly distinct from the background (e.g. the Juno clump). Clans are groupings which merge very gradually into the background density and/or have a complex internal structure making it difficult to decide whether they are one complex group or several unrelated overlapping groups (e.g. the Flora family has been called a clan). Tribes are groups that are less certain to be statistically significant against the background either because of small density or large uncertainty in the orbital parameters of the members.
List
Most prominent families
Mean of the "core" members found in HCM and WAM analyses by Zappala et al. (1995), rounded to 2 significant digits. That analysis considered 12,487 asteroids, but currently almost half a million are known (see § All families for a 2015 census). Hence, the number of currently catalogued asteroids that are members of a given family is likely to be greater than the value in this column by a similar factor of roughly 40.
| Family Name | Named After | orbital elements | Size | Alternate Names | |||
|---|---|---|---|---|---|---|---|
| a (AU) | e | i (°) | approx. % of asteroids | Members in Zappalà HCM analysis[A] | |||
| Eos (Eoan) | 221 Eos | 2.99 to 3.03 | 0.01 to 0.13 | 8 to 12 | 480 | ||
| Eunomia(n) | 15 Eunomia | 2.53 to 2.72 | 0.08 to 0.22 | 11.1 to 15.8 | 5% | 370 | |
| Flora (Florian) | 8 Flora | 2.15 to 2.35 | 0.03 to 0.23 | 1.5 to 8.0 | 4–5% | 590 | Ariadne(an) family after 43 Ariadne |
| Hygiea(n) | 10 Hygiea | 3.06 to 3.24 | 0.09 to 0.19 | 3.5 to 6.8 | 1% | 105 | |
| Koronis (Koronian) | 158 Koronis | 2.83 to 2.91 | 0 to 0.11 | 0 to 3.5 | 310 | ||
| Maria(n) | 170 Maria | 2.5 to 2.706 | 12 to 17 | 80 | |||
| Nysa (Nysian) | 44 Nysa | 2.41 to 2.5 | 0.12 to 0.21 | 1.5 to 4.3 | 380 | Hertha (Herthian) family after 135 Hertha | |
| Themis (Themistian) | 24 Themis | 3.08 to 3.24 | 0.09 to 0.22 | 0 to 3 | 530 | ||
| Vesta (Vestian) | 4 Vesta | 2.26 to 2.48 | 0.03 to 0.16 | 5.0 to 8.3 | 6% | 240 | |
All families
In 2015, a study identified 122 notable families with a total of approximately 100,000 member asteroids, based on the entire catalog of numbered minor planets, which consisted of almost 400,000 numbered bodies at the time (see catalog index for a current listing of numbered minor planets).[3]:23 The data has been made available at the "Small Bodies Data Ferret".[4] The first column of this table contains the Family Identification Number (FIN).
| FIN | Family | Lbl | # of Members | Loc. | Taxonomy | Parent | LoMP |
|---|---|---|---|---|---|---|---|
| 001 | Hilda family | HIL | 409 | rim | C | 153 Hilda; adj. Hildian; a-e-i: (3.7 to 4.2; > 0.07; < 20°) | list |
| 002 | Schubart family | SHU | 352 | rim | C | 1911 Schubart (Hildian) | list |
| 003 | Hungaria family | H | 2965 | rim | E | 434 Hungaria | list |
| 004 | Hektor family | HEK | 12 | rim | – | 624 Hektor (Jupiter trojan) | list |
| 005 | Eurybates family | ERY | 218 | rim | CP | 3548 Eurybates (Jupiter trojan) | list |
| 006 | RJ family | 006 | 7 | rim | – | (9799) 1996 RJ (Jupiter trojan) | list |
| 007 | James Bond family | 007 | 1 | rim | ASP | 9007 James Bond | list |
| 008 | Arkesilaos family | ARK | 37 | rim | – | 20961 Arkesilaos | list |
| 009 | Ennomos family | ENM | 30 | rim | – | 4709 Ennomos | list |
| 010 | UV209 family | 010 | 13 | rim | – | (247341) 2001 UV209 | list |
| 401 | Vesta family | V | 15252 | inner | V | 4 Vesta | list |
| 402 | Flora family | FLO | 13786 | inner | S | 8 Flora | list |
| 403 | Baptistina family | BAP | 2500 | inner | X | 298 Baptistina | list |
| 404 | Massalia family | MAS | 6424 | inner | S | 20 Massalia, adj. Massalian, a-e-i: (2.37 to 2.45; 0.12 to 0.21; 0.4 to 2.4) | list |
| 405 | Nysa family (Polana) | NYS | 19073 | inner | SFC | 44 Nysa/142 Polana | list/(b) |
| 406 | Erigone family | ERI | 1776 | inner | CX | 163 Erigone, adj. Erigonian | list |
| 407 | Clarissa family | CLA | 179 | inner | X | 302 Clarissa | list |
| 408 | Sulamitis family | SUL | 303 | inner | C | 752 Sulamitis | list |
| 409 | Lucienne family | LCI | 142 | inner | S | 1892 Lucienne | list |
| 410 | Euterpe family | EUT | 474 | inner | S | 27 Euterpe | list |
| 411 | Datura family | DAT | 6 | inner | S | 1270 Datura | list |
| 412 | Lucascavin family | LCA | 3 | inner | S | 21509 Lucascavin | list |
| 413 | Klio family | KLI | 330 | inner | C | 84 Klio | list |
| 414 | Chimaera family | CIM | 108 | inner | CX | 623 Chimaera | list |
| 415 | Chaldaea family | CHL | 132 | inner | C | 313 Chaldaea | list |
| 416 | Svea family | SVE | 48 | inner | CX | 329 Svea | list |
| 417 | GB11 family | 417 | 9 | inner | – | (108138) 2001 GB11 | list |
| 701 | Phocaea family | PHO | 1989 | inner | S | 25 Phocaea | list |
| 501 | Juno family | JUN | 1684 | middle | S | 3 Juno | list |
| 502 | Eunomia family | EUN | 5670 | middle | S | 15 Eunomia | list |
| 503 | – | – | – | – | – | – | – |
| 504 | Nemesis family | NEM | 1302 | middle | C | 128 Nemesis, adj. Nemesian; Concordia(n) family after 58 Concordia) | list |
| 505 | Adeona family | ADE | 2236 | middle | C | 145 Adeona | list |
| 506 | Maria family | MAR | 2940 | middle | S | 170 Maria | list |
| 507 | Padua family | PAD | 1087 | middle | X | 363 Padua | list |
| 508 | Aeolia family | AEO | 296 | middle | X | 396 Aeolia | list |
| 509 | Chloris family | CLO | 424 | middle | C | 410 Chloris, adj. Chloridian | list |
| 510 | Misa family | MIS | 702 | middle | C | 569 Misa, adj. Misian | list |
| 511 | Brangane family | BRG | 195 | middle | S | 606 Brangane | list |
| 512 | Dora family | DOR | 1259 | middle | C | 668 Dora, adj. Dorian | list |
| 513 | Merxia family | MRX | 1215 | middle | S | 808 Merxia, adj. Merxian | list |
| 514 | Agnia family | AGN | 2125 | middle | S | 847 Agnia | list |
| 515 | Astrid family | AST | 489 | middle | C | 1128 Astrid, adj. Astridian | list |
| 516 | Gefion family | GEF | 2547 | middle | S | 1272 Gefion, adj. Gefionian; a-e-i: (2.74 to 2.82; 0.08 to 0.18; 7.4 to 10.5); alt: Ceres (Cererian) family after 1 Ceres and Minerva (Minervian) family after 93 Minerva | list |
| 517 | König family | KON | 354 | middle | CX | 3815 König | list |
| 518 | Rafita family | RAF | 1295 | middle | S | 1644 Rafita, adj. Rafitian | list |
| 519 | Hoffmeister family | HOF | 1819 | middle | CF | 1726 Hoffmeister | list |
| 520 | Iannini family | IAN | 150 | middle | S | 4652 Iannini | list |
| 521 | Kazuya family | KAZ | 44 | middle | S | 7353 Kazuya | list |
| 522 | Ino family | INO | 463 | middle | S | 173 Ino | list |
| 523 | Emilkowalski family | EMI | 4 | middle | S | 14627 Emilkowalski | list |
| 524 | YC2 family | 524 | 3 | middle | S | (16598) 1992 YC2 | list |
| 525 | Schulhof family | SHF | 6 | middle | S | 2384 Schulhof | list |
| 526 | BY6 family | 526 | 58 | middle | C | (53546) 2000 BY6 | list |
| 527 | Lorre family | LOR | 2 | middle | C | 5438 Lorre | list |
| 528 | Leonidas family | LEO | 135 | middle | CX | 2782 Leonidas | list |
| 529 | Vibilia family | VIB | 180 | middle | C | 144 Vibilia | list |
| 530 | Phaeo family | PAE | 146 | middle | X | 322 Phaeo | list |
| 531 | Mitidika family | MIT | 653 | middle | C | 2262 Mitidika | list |
| 532 | Henan family | HEN | 1872 | middle | L | 2085 Henan | list |
| 533 | Hanna family | HNA | 280 | middle | CX | 1668 Hanna | list |
| 534 | Karma family | KRM | 124 | middle | CX | 3811 Karma | list |
| 535 | Witt family | WIT | 1618 | middle | S | 2732 Witt | list |
| 536 | Xizang family | XIZ | 275 | middle | – | 2344 Xizang | list |
| 537 | Watsonia family | WAT | 99 | middle | L | 729 Watsonia | list |
| 538 | Jones family (asteroids) | JNS | 22 | middle | T | 3152 Jones | list |
| 539 | Aeria family | AER | 272 | middle | X | 369 Aeria | list |
| 540 | Julia family (asteroids) | JUL | 33 | middle | S | 89 Julia | list |
| 541 | Postrema family | POS | 108 | middle | CX | 1484 Postrema | list |
| 801 | Pallas family | PAL | 128 | middle | B | 2 Pallas | list |
| 802 | Gallia family | GAL | 182 | middle | S | 148 Gallia | list |
| 803 | Hansa family | HNS | 1094 | middle | S | 480 Hansa adj. Hansian; a-e-i: (~2.66; ~0.06; ~22.0°)[5] | list |
| 804 | Gersuind family | GER | 415 | middle | S | 686 Gersuind | list |
| 805 | Barcelona family | BAR | 306 | middle | S | 945 Barcelona | list |
| 806 | Tina family | TIN | 96 | middle | X | 1222 Tina | list |
| 807 | Brucato family | BRU | 342 | middle | CX | 4203 Brucato | list |
| 601 | Hygiea family | HYG | 4854 | outer | CB | 10 Hygiea | list |
| 602 | Themis family | THM | 4782 | outer | C | 24 Themis | list |
| 603 | Sylvia family | SYL | 255 | outer | X | 87 Sylvia | list |
| 604 | Meliboea family | MEL | 444 | outer | C | 137 Meliboea, adj. Meliboean | list |
| 605 | Koronis family | KOR | 5949 | outer | S | 158 Koronis | list |
| 606 | Eos family | EOS | 9789 | outer | K | 221 Eos | list |
| 607 | Emma family | EMA | 76 | outer | C | 283 Emma | list |
| 608 | Brasilia family | BRA | 579 | outer | X | 293 Brasilia, adj. Brasilian | list |
| 609 | Veritas family | VER | 1294 | outer | CPD | 490 Veritas, adj. Veritasian; alt: Undina (Undinian) family after 92 Undina | list |
| 610 | Karin family | KAR | 541 | outer | S | 832 Karin | list |
| 611 | Naëma family | NAE | 301 | outer | C | 845 Naëma, adj. Naëmian | list |
| 612 | Tirela family | TIR | 1395 | outer | S | 1400 Tirela (Klumpkea) | list |
| 613 | Lixiaohua family | LIX | 756 | outer | CX | 3556 Lixiaohua | list |
| 614 | Telramund family | TEL | 468 | outer | S | 9506 Telramund | list |
| 615 | FY12 family | 615 | 104 | outer | CX | (18405) 1993 FY12 | list |
| 616 | Charis family | CHA | 808 | outer | C | 627 Charis | list |
| 617 | Theobalda family | THB | 376 | outer | CX | 778 Theobalda, adj. Theobaldian; a-e-i: (3.16 to 3.19; 0.24 to 0.27; 14 to 15) | list |
| 618 | Terentia family | TRE | 79 | outer | C | 1189 Terentia | list |
| 619 | Lau family | LAU | 56 | outer | S | 10811 Lau | list |
| 620 | Beagle family | BGL | 148 | outer | C | 656 Beagle | list |
| 621 | Koronis family (II) | K-2 | 246 | outer | S | 158 Koronis "second family" | list |
| 622 | Terpsichore family | TRP | 138 | outer | C | 81 Terpsichore | list |
| 623 | Fringilla family | FIR | 134 | outer | X | 709 Fringilla | list |
| 624 | Durisen family | DUR | 27 | outer | X | 5567 Durisen | list |
| 625 | Yakovlev family | YAK | 67 | outer | C | 5614 Yakovlev | list |
| 626 | San Marcello family | SAN | 144 | outer | X | 7481 San Marcello | list |
| 627 | YB3 family | 627 | 38 | outer | CX | (15454) 1998 YB3 | list |
| 628 | CG1 family | 628 | 248 | outer | S | (15477) 1999 CG1 | list |
| 629 | XT17 family | 629 | 58 | outer | S | (36256) 1999 XT17 | list |
| 630 | Aegle family | AEG | 99 | outer | CX | 96 Aegle | list |
| 631 | Ursula family | URS | 1466 | outer | CX | 375 Ursula | list |
| 632 | Elfriede family | ELF | 63 | outer | C | 618 Elfriede | list |
| 633 | Itha family | ITH | 54 | outer | S | 918 Itha | list |
| 634 | Inarradas family | INA | 38 | outer | CX | 3438 Inarradas | list |
| 635 | Anfimov family | ANF | 58 | outer | S | 7468 Anfimov | list |
| 636 | Marconia family | MRC | 34 | outer | CX | 1332 Marconia | list |
| 637 | UJ87 family | 637 | 64 | outer | CX | (106302) 2000 UJ87 | list |
| 638 | Croatia family | CRO | 93 | outer | X | 589 Croatia | list |
| 639 | Imhilde family | IMH | 43 | outer | CX | 926 Imhilde | list |
| 640 | Gibbs family | GBS | 8 | outer | – | 331P/Gibbs "P/2012 F5 (Gibbs)" | – |
| 641 | Juliana family | JLI | 76 | outer | CX | 816 Juliana | list |
| 901 | Euphrosyne family | EUP | 2035 | outer | C | 31 Euphrosyne | list |
| 902 | Alauda family | ALA | 1294 | outer | B | 702 Alauda | list |
| 903 | Ulla family | ULA | 26 | outer | X | 909 Ulla | list |
| 904 | Luthera family | LUT | 163 | outer | X | 1303 Luthera | list |
| 905 | Armenia family | ARM | 40 | outer | C | 780 Armenia | list |
Other families
Other divergent and non main-belt families[C]
| Family Name | Named After | orbital elements | Size | Alternate Names | |||
|---|---|---|---|---|---|---|---|
| a (AU) | e | i (°) | approx. % of asteroids | Members in Zappalà HCM analysis | |||
| Bower(ian) | 1639 Bower | 13 | Endymion (Endymionian) family after 342 Endymion | ||||
| Lydia(n) | 110 Lydia | 38 | |||||
| TNO families:[D] | |||||||
| Haumea(n) | 136108 Haumea | ~43 | ~0.19 | ~28 | |||
Legend:
| |||||||
See also Category:Asteroid groups and families, which names some less prominent and uncertain groupings.
See also
- Proper orbital elements
- Category:Asteroid groups and families
- Haumea
References
- ↑ Michael E. Brown, Kristina M. Barkume, Darin Ragozzine & Emily L. Schaller, A collisional family of icy objects in the Kuiper belt, Nature, 446, (March 2007), pp 294-296.
- ↑ David Nesvorný, Brian L. Enke, William F. Bottke, Daniel D. Durda, Erik Ashaug & Derek C. Richardson Karin cluster formation by asteroid impact, Icarus 183, (2006) pp 296-311.
- ↑ Nesvorný, D.; Broz, M.; Carruba, V. (December 2014). "Identification and Dynamical Properties of Asteroid Families" (PDF). Asteroids IV: 297–321. Bibcode:2015aste.book..297N. arXiv:1502.01628
. doi:10.2458/azu_uapress_9780816532131-ch016. Retrieved 23 June 2017. - ↑ "Small Bodies Data Ferret". Nesvorny HCM Asteroid Families V3.0. Retrieved 22 July 2017.
- ↑ The Hansa Family: A New High-Inclination Asteroid Family
Further reading
- Bendjoya, Philippe; and Zappalà, Vincenzo; "Asteroid Family Identification", in Asteroids III, pp. 613–618, University of Arizona Press (2002), ISBN 0-8165-2281-2
- V. Zappalà et al. "Physical and Dynamical Properties of Asteroid Families", in Asteroids III, pp. 619–631, University of Arizona Press (2002), ISBN 0-8165-2281-2
- A. Cellino et al. "Spectroscopic Properties of Asteroid Families", in Asteroids III, pp. 633–643, University of Arizona Press (2002), ISBN 0-8165-2281-2
- Hirayama, Kiyotsugu; "Groups of asteroids probably of common origin", Astronomical Journal, Vol. 31, No. 743, pp. 185-188 (October 1918).
- Nesvorný, David; Bottke Jr., William F.; Dones, Luke; and Levison, Harold F.; "The recent breakup of an asteroid in the main-belt region", Nature, Vol. 417, pp. 720-722 (June 2002).
- Zappalà, Vincenzo; Cellino, Alberto; Farinella, Paolo; and Knežević, Zoran; "Asteroid families I - Identification by hierarchical clustering and reliability assessment", Astronomical Journal, Vol. 100, p. 2030 (December 1990).
- Zappalà, Vincenzo; Cellino, Alberto; Farinella, Paolo; and Milani, Andrea; "Asteroid families II - Extension to unnumbered multiopposition asteroids", Astronomical Journal, Vol. 107, pp. 772-801 (February 1994)
- V. Zappalà et al. Asteroid Families: Search of a 12,487-Asteroid Sample Using Two Different Clustering Techniques, Icarus, Vol. 116, p. 291 (1995.)
- M. S. Kelley & M. J. Gaffey 9 Metis and 113 Amalthea: A Genetic Asteroid Pair, Icarus Vol. 144, p. 27 (2000).
External links
- Planetary Data System - Asteroid Families dataset, as per the Zappalà 1995 analysis.
- Latest calculations of proper elements for numbered minor planets at astDys.
- Asteroid (and Comet) Groups by Petr Scheirich (with excellent plots).