22 Kalliope
Kalliope and satellite Linus as seen by the W.M. Keck II telescope in 2010 | |
Discovery | |
---|---|
Discovered by | John Russell Hind |
Discovery date | November 16, 1852 |
Designations | |
Pronunciation | /kəˈlaɪ.əpiː/ kə-LY-ə-pee |
Named after | Calliopē |
none | |
Main belt | |
Orbital characteristics[1] | |
Epoch 2010-Jul-23 (JD 2455400.5) | |
Aphelion |
479.98 Gm 3.2085 AU |
Perihelion |
391.03 Gm 2.6139 AU |
435.09 Gm 2.9112 AU | |
Eccentricity | 0.10213 |
1814.3 d (4.97 yr) | |
Average orbital speed | 17.42 km/s |
282.54° | |
Inclination | 13.703° |
66.17° | |
355.03° | |
Known satellites | Linus |
Physical characteristics | |
Dimensions |
235×144×124 km[2] 166.2±2.8 km[2] 181 ± 4.6 km (IRAS)[1] |
Mean radius | 83.1 ± 1.4 km[2] |
Mass | 8.16 ± 0.26×1018 kg |
Mean density | 3.35 ± 0.33 g/cm³[2] |
0.079 m/s² | |
0.114 km/s | |
0.1728 d (4.148 h)[1] | |
Albedo | 0.17[2] |
Temperature |
~161 K max: 240 K (−32 °C) |
Spectral type | M (Tholen)[1] |
6.45[1] | |
|
22 Kalliope[3] is a large M-type asteroid from the asteroid belt discovered by J. R. Hind on November 16, 1852. It is named after Calliope, the Greek Muse of epic poetry. It is orbited by a small moon named Linus.
Characteristics
Kalliope is somewhat elongated, approximately 166 km in diameter,[2] and slightly asymmetric, as evidenced by resolved images taken with the VLT at the European Southern Observatory. This new diameter, which was measured by observing mutual eclipses of Kalliope and Linus, is 8% smaller than that calculated from IRAS observations.[2]
The spectrum of Kalliope is an M-type, indicating that its surface may be partially composed of iron–nickel metal. The asteroid's density is about 3.4 g/cm3.[2] Since the asteroid is likely to be a rubble pile, accounting for a possible porosity of 20–40% leads to the material density of 4.2–5.8 g/cm3, which means that Kalliope is probably made of a mixture of metal with silicates.[2] Spectroscopic studies have shown, however, evidence of hydrated minerals[4] and silicates,[5] which indicate rather a stony surface composition. Kalliope also has a low radar albedo,[6] which is inconsistent with a purely metallic surface.
Lightcurve analysis indicates that Kalliope's pole most likely points towards ecliptic coordinates (β, λ) = (−23°, 20°) with a 10° uncertainty,[7][8] which gives Kalliope an axial tilt of 103°. Kalliope's rotation is then slightly retrograde.
Satellite
Kalliope has one known natural satellite, Linus, or (22) Kalliope I Linus. It is quite large, being about 28 km in diameter, and would be a sizeable asteroid by itself. It orbits about 1100 km from the center of Kalliope, equivalent to about 13.2 Kalliope radii.[2] Linus was discovered on August 29, 2001 by Jean-Luc Margot and Michael E. Brown, while another team led by William Merline also independently detected the moon 3 days later.[6][8]
First stellar occultation
On November 7, 2006, the first stellar occultation by the satellite of an asteroid (Linus) was successfully observed by a group of Japanese observers[9] according to a prediction that was made just one day before by Berthier et al.[10] based on more than 5 years of regular observations of Kalliope binary system using adaptive optics systems on ground-based telescopes. The observed chords of Linus give a unique opportunity to estimate the size of the moonlet which was estimated to 20–28 km.
References
- 1 2 3 4 5 "JPL Small-Body Database Browser: 22 Kalliope" (2010-06-02 last obs). Retrieved 2010-07-22.
- 1 2 3 4 5 6 7 8 9 10 Descamps, P.; Marchis, F.; et al. (2008). "New determination of the size and bulk density of the binary asteroid 22 Kalliope from observations of mutual eclipses". Icarus. 196 (2): 578–600. arXiv:0710.1471. Bibcode:2008Icar..196..578D. doi:10.1016/j.icarus.2008.03.014.
- ↑ Pronounced /kəˈlaɪ.əpiː/ kə-LY-ə-pee
- ↑ A.S. Rivkin (2000). "The nature of M-class asteroids from 3-micron observations". Icarus. 145 (2): 351–368. Bibcode:2000Icar..145..351R. doi:10.1006/icar.2000.6354.
- ↑ D.F. Lupishko (1982). "UBV photometry of the M-type asteroids 16 Psyche and 22 Kalliope". Solar System Research. 16: 75.
- 1 2 J.L. Margot & M.E. Brown (2003). "A Low-Density M-type Asteroid in the Main Belt". Science. 300 (5627): 1939–1942. Bibcode:2003Sci...300.1939M. doi:10.1126/science.1085844. PMID 12817147.
- ↑ M. Kaasalainen (2002). "Models of Twenty Asteroids from Photometric Data" (PDF). Icarus. 159 (2): 369–395. Bibcode:2002Icar..159..369K. doi:10.1006/icar.2002.6907.
- 1 2 F. Marchis (2003). "A three-dimensional solution for the orbit of the asteroidal satellite of 22 Kalliope". Icarus. 165 (1): 112–120. Bibcode:2003Icar..165..112M. doi:10.1016/S0019-1035(03)00195-7.
- ↑ M. Soma, et al. (2006). "'Occulation by Kalliope and Linus". CBET. 732: 1. Bibcode:2006CBET..732....1S.
- ↑ J. Berthier, et al. (2004). "'Prediction of stellar occultations by satellite of asteroids". Dps-Aas. 32.23: 1142. Bibcode:2004DPS....36.3223B.
External links
- shape model deduced from lightcurve
- orbit diagram for Linus
- A different VLT image of Kalliope and Linus
- Data sheet at Johnston's Archive, includes some other parameters.
- , Prediction and Reduction of Stellar Occultations of Binary Asteroids.
- 22 Kalliope at the JPL Small-Body Database