Jupiter's natural satellites

Jupiter has many natural satellites.

Contents

1 Discovery of the moons

1.1 The most recent discoveries

2 Table of known moons

Discovery of the moons

The Galiean moons: Shown from left to right in order of increasing distance from Jupiter, Io is closest, followed by Europa, Ganymede, and Callisto.

The first moons of Jupiter to be discovered were the large Galilean moons, discovered by Galileo in 1610. Over the next four centuries, nine smaller moons were discovered by ground-based astronomers.

The Voyager 1 mission discovered three inner moons in 1979, bringing the total then known to 16 (17 if you count Themisto, which had been found but then lost in 1975). The total rested there until 1999, since when sensitive ground-based detectors have found a further 47 (or 46) tiny moons in long, eccentric, generally retrograde orbits. They average 3 kilometres in diameter, and the largest is barely 9 km across. All of these moons are thought to be captured asteroidal or perhaps cometary bodies, possibly fragmented into several pieces, but very little is actually known about them. The total number of known moons of Jupiter now stands at 63, currently the most of any planet in the solar system. Many additional tiny moons may exist that have not yet been discovered.

The most recent discoveries

On October 6 1999, the Spacewatch programme discovered an asteroid, 1999 UX₁₈. But it was soon realised that this was in fact a new moon of Jupiter, Callirrhoe. One year later, between November 23 and December 5, 2000, the team led by Scott S. Sheppard and David C. Jewitt of the University of Hawaii began a systematic search for small irregular moons of Jupiter. The other members of the team included, at various times, Yanga R. Fernández , Eugene A. Magnier , Scott Dahm , Aaron Evans , Henry H. Hsieh , Karen J. Meech , John L. Tonry , David J. Tholen (all from the University of Hawaii), Jan Kleyna (Cambridge University), Brett J. Gladman (University of Toronto), John J. Kavelaars (Hertzberg Institute of Astrophysics ), Jean-Marc Petit (Observatoire de Besançon ) and Rhiannon Lynne Allen (University of Michigan / University of British Columbia).

The team used the world's two largest CCD cameras, mounted on two of the thirteen telescopes atop Mauna Kea in Hawaii: the Subaru (8.3 m diameter) and the Canada-France-Hawaii (3.6 m). The 2000 observations revealed ten new moons, putting the count at 28 (Themisto had been rediscovered at the beginning of 2000).

The following year, on December 9-11, 2001, eleven other moons were discovered, bringing the total to 39. The year 2002 bore less fruit, netting only one moon, Arche. However, four months later, between February 5 and 9, 2003, 23 more moons were found.

References:

Table of known moons

Note that the outer satellites do not follow the simple period / axis relationship suggested by Kepler's third law because of the gravitational influence of the sun distorting the orbits. The table below is sorted in order of increasing period, which is not the same as the order of increasing mean orbital radius.

Name (Pronunciation key)		Diameter (km)	Mass (kg)	Orbital radius (km)	Orbital period (d)	Inclination (°)	Eccentricity	Group
Metis	mee'-tis	43	1.2E+16	128 000	0.295	0.019°	0.0012	Amalthea
Adrastea	ad'-rus-tee'-a	26×20×16	7.5E+14	129 000	0.298	0.054°	0.0018
Amalthea	am'-ul-thee'-a	262×146×134	0.2E+18	181 400	0.498	0.388°	0.0031
Thebe	thee'-bee	110×90	0.1E+18	221 900	0.675	1.070°	0.0177
Io	eye'-oh	3643	0.9E+22	421 800	1.769	0.036°	0.0041	Galileans
Europa	ew-roh'-pa	3122	0.5E+22	671 100	3.551	0.469°	0.0094
Ganymede	gan'-i-meed	5262	1.5E+22	1 070 400	7.155	0.170°	0.0011
Callisto	ka-lis'-toh	4821	1.1E+22	1 882 700	6.690	0.187°	0.0074
Themisto	the-mis'-toh	8	0.7E+14	7 284 000	130.020	43.259°	0.2426	Themisto
Leda	lee'-da	20	0.1E+16	11 165 000	240.920	27.457°	0.1636	Himalia
Himalia	hye-mal'-ee-a	170	0.7E+18	11 461 000	250.560	27.496°	0.1623
Lysithea	lye-sith'-ee-a	36	0.6E+16	11 717 000	259.200	28.302°	0.1124
Elara	ee-lair'-a	86	8.7E+16	11 741 000	259.640	26.627°	0.2174
S/2000 J 11		4	9.0E+12	12 555 000	286.950	28.273°	0.2484
Carpo	kar'-poh	3	4.5E+12	16 989 000	456.100	51.395°	0.4297	?
S/2003 J 12		1	0.1E+12	17 582 000	489.500	151.140°	0.5095	?
Euporie	ew-por'-ee-a	2	1.5E+12	19 304 000	550.740	145.767°	0.1432	Ananke?
S/2003 J 3		2	1.5E+12	20 221 000	583.880	147.550°	0.1970
S/2003 J 18		2	1.5E+12	20 514 000	596.590	146.104°	0.0221
S/2003 J 16		2	1.5E+12	20 957 000	616.360	148.537°	0.2246	Ananke
Mneme	nee'-mee	2	1.5E+12	21 069 000	620.040	148.635°	0.2273
Euanthe	ew-an'-thee	3	4.5E+12	20 797 000	620.490	148.910°	0.2321
Orthosie	or-thoh'-see-a	2	1.5E+12	20 720 000	622.560	145.921°	0.2808	Ananke?
Harpalyke	har-pal'-i-kee	4	0.1E+14	20 858 000	623.310	148.644°	0.2268	Ananke
Praxidike	prak-sid'-i-kee	7	0.4E+14	20 907 000	625.380	148.967°	0.2308
Thyone	thye-oh'-nee	4	9.0E+12	20 939 000	627.210	148.509°	0.2286
Thelxinoe	thel-zin'-oh-ee	2	1.5E+12	21 162 000	628.090	151.417°	0.2206	Ananke?
Ananke	a-nang'-kee	28	0.3E+16	21 276 000	629.770	148.889°	0.2435	Ananke
Iocaste	eye'-o-kas'-tee	5	0.2E+14	21 061 000	631.600	149.429°	0.2160	Ananke
Hermippe	hur-mip'-ee	4	9.0E+12	21 131 000	633.900	150.725°	0.2096	Ananke?
Helike	hel'-i-kee	4	9.0E+12	21 263 000	634.770	154.773°	0.1558
S/2003 J 15		2	1.5E+12	22 627 000	689.770	146.501°	0.1910
S/2003 J 17		2	1.5E+12	22 992 000	714.470	164.917°	0.2378	Carme
S/2003 J 10		2	1.5E+12	23 041 000	716.250	165.086°	0.4295	Carme?
Eurydome	ew-rid'-o-mee?	3	4.5E+12	22 865 000	717.330	150.274°	0.2759	Pasiphaë?
Pasithee	pa-sith'-ee-a	2	1.5E+12	23 004 000	719.440	165.138°	0.2675	Carme
Chaldene	?	4	7.5E+12	23 100 000	723.700	165.191°	0.2519
Arche	ar'-kee	3	4.5E+12	22 931 000	723.900	165.001°	0.2588
Isonoe	eye-son'-oh-ee?	4	7.5E+12	23 155 000	726.250	165.268°	0.2471
Erinome	?	3	4.5E+12	23 196 000	728.510	164.934°	0.2665
Kale	kay'-lee	2	1.5E+12	23 217 000	729.470	164.996°	0.2599
Aitne	et'-nee	3	4.5E+12	23 229 000	730.180	165.091°	0.2643
Taygete	tay-ij'-i-tee	5	0.2E+14	23 280 000	732.410	165.272°	0.2525
S/2003 J 23		2	1.5E+12	23 563 000	732.440	146.314°	0.2714	Pasiphaë
S/2003 J 9		1	0.1E+12	23 384 000	733.290	165.079°	0.2632	Carme
Carme	kar'-mee	46	1.3E+16	23 404 000	734.170	164.907°	0.2533
S/2003 J 5		4	9.0E+12	23 495 000	738.730	165.247°	0.2478
Hegemone	hi-jem'-a-nee	3	4.5E+12	23 947 000	739.600	155.214°	0.3276	Pasiphaë
S/2003 J 19		2	1.5E+12	23 533 000	740.420	165.153°	0.2556	Carme
Kalyke	kal'-i-kee	5	0.2E+14	23 566 000	742.030	165.159°	0.2465	Carme
Pasiphaë	pa-sif'-a-ee	60	3.0E+16	23 624 000	743.630	151.431°	0.4090	Pasiphaë
Eukelade	ew-kel'-a-dee	4	9.0E+12	23 661 000	746.390	165.482°	0.2721	Carme
Sponde	spon'-dee	2	1.5E+12	23 487 000	748.340	150.998°	0.3121	Pasiphaë
Cyllene	si-lee'-nee	2	1.5E+12	23 951 000	751.940	150.123°	0.4116
Megaclite	meg'-a-klye'-tee?	5	0.2E+14	23 493 000	752.880	152.769°	0.4197
S/2003 J 4		2	1.5E+12	23 930 000	755.240	149.581°	0.3618
Callirrhoe	ka-leer'-oh-ee	9	0.9E+14	24 103 000	758.770	147.158°	0.2828
Sinope	si-noh'-pee	38	0.7E+16	23 939 000	758.900	158.109°	0.2495
Autonoe	aw-ton'-oh-ee	4	9.0E+12	24 046 000	760.950	152.416°	0.3168
Aoede	ay-ee'-dee	4	9.0E+12	23 981 000	761.500	158.257°	0.4322
Kallichore	ka-lik'-a-ree	2	1.5E+12	24 043 000	764.730	165.501°	0.2640	Carme?
S/2003 J 14		2	1.5E+12	24 011 000	779.180	144.529°	0.3351	Pasiphaë
S/2003 J 2		2	1.5E+12	29 541 000	979.990	160.638°	0.2255	?

The orbits of the unnamed moons are still susceptible of improvement.

Grouping the moons

The interior groups seem natural: Amalthea's, the Galilean moons. Themisto is isolated in space. The Himalia group is "tight", spread over barely 1.4 Gm in semi-major axis and 1.6° in inclination (27.5 ± 0.8°). The eccentricities vary between 0.11 and 0.25. Carpo and S/2003 J 12 are two other isolated cases, and so is S/2003 J 2, the most exterior moon.

What is left of the outer retrograde irregular satellites of Jupiter can be grouped in three families, based on shared orbital characteristics and bearing the name of the largest member in each case. These families are clumps in semi-major axis, but also in inclination and in eccentricity. In the two plots below, Carme's group is in orange and Ananke's in yellow.

Carme's group is obvious, centered on a = 23 404 Mm; i = 165.2±0.3° and e = 0.238–0.272. Only S/2003 J 10 seems somewhat apart, because of its great eccentricity.

Ananke's group is centered on a = 21 276 Mm; i = 149.0±0.5° and e = 0.216–0.244; but its borders are less definite. The eight core members (S/2003 J 16, Mneme, Euanthe, Orthosie, Harpalyke, Praxidike, Thyone, Thelxinoe, Ananke, Iocaste) are well-clumped, but the attribution of the remaining eight members to the group is debatable to varying degrees.

Pasiphaë's group, finally, picks up the remainder, with the exception of the moons at the inner and outer limits of the groups (S/2003 J 12 and S/2003 J 2); it is centered on a = 23 624 Mm; i = 151.4±6.9° and e = 0.156–0.432 (note the much larger spreads). If it is real, it must be ancient to explain the dispersion of its membership.

Naming notes

Some asteroids share the same names as moons of Jupiter: 9 Metis, 38 Leda, 52 Europa, 85 Io, 113 Amalthea, 239 Adrastea, 1036 Ganymed.

Note that the satellites discovered between 1904 and 1951 (Himalia, Elara, Pasiphaë, Sinope, Lysithea, Carme and Ananke) were not officially named until 1975, well after their discoverers had passed away. They were simply known by their Roman numeral designations (Jupiter VI through Jupiter XII). See Naming of natural satellites.

External links

Categories: Jupiter's moons

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01-04-2007 01:21:04

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