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90482 Orcus

January 07, 2023

For the Roman god, see Orcus (mythology). For other uses, see Orcus (disambiguation).

Orcus (minor-planet designation 90482 Orcus, provisional designation 2004 DW) is a trans-Neptunian dwarf planet with a large moon, Vanth.[6] It has a diameter of 910 km (570 mi). The surface of Orcus is relatively bright with albedo reaching 23 percent, neutral in color and rich in water ice. The ice is predominantly in crystalline form, which may be related to past cryovolcanic activity. Other compounds like methane or ammonia may also be present on its surface. Orcus was discovered by American astronomers Michael Brown, Chad Trujillo, and David Rabinowitz on 17 February 2004.

90482 Orcus
Orcus and its moon Vanth imaged by the Hubble Space Telescope in 2006
Discovery[1][2]
Discovered byM. E. Brown
C. Trujillo
D. Rabinowitz
Discovery date17 February 2004
Designations
(90482) Orcus
Pronunciation/ˈɔːrkəs/[7]
Named after
Orcus (Roman mythology)[3]
2004 DW
TNO[1] · plutino[4][5]
dwarf planet[6]
AdjectivesOrcean /ˈɔːrsiən/[8]
Orbital characteristics[1]
Epoch 31 May 2020 (JD 2459000.5)
Uncertainty parameter 2
Observation arc68.16 yr (24,894 days)
Earliest precovery date8 November 1951
Aphelion48.067 AU (7.1907 Tm)
Perihelion30.281 AU (4.5300 Tm)
39.174 AU (5.8603 Tm)
Eccentricity0.22701
245.19 yr (89,557 days)
181.735°
0° 0m 14.472s / day
Inclination20.592°
268.799°
≈ 9 January 2143[9]
±4 days
72.310°
Known satellitesVanth
Physical characteristics
Dimensions910+50
−40 km[10] 917±25 km[11]
Mass(6.348±0.019)×1020 kg (system)[6]
Mean density
1.53+0.15
−0.13 g/cm3[11]
Equatorial surface gravity
≈ 0.2 m/s2
Equatorial escape velocity
≈ 0.43 km/s
0.231+0.018
−0.011[11]
Temperature< 44 K[12]
(neutral)[12]
B–V =0.68[13]
V–R = 0.37[13]
19.1 (opposition)[14]
2.31±0.03 (integral),[11] 2.41±0.05[15]

Orcus is a plutino, a trans-Neptunian object that is locked in a 2:3 resonance with the ice giant Neptune, making two revolutions around the Sun to every three of Neptune's.[4] This is much like Pluto, except that the phase of Orcus's orbit is opposite to Pluto's: Orcus is at aphelion (most recently in 2019) around when Pluto is at perihelion (most recently in 1989) and vice versa.[16] Orcus is the largest known plutino after Pluto itself. The perihelion of Orcus's orbit is around 120° from that of Pluto, while the eccentricities and inclinations are similar. Because of these similarities and contrasts, along with its large moon Vanth that recalls Pluto's large moon Charon, Orcus has been regarded as the anti-Pluto.[17] This was a major consideration in selecting its name, as the deity Orcus was the Roman/Etruscan equivalent of the Roman/Greek Pluto.[17]

History

Discovery

 
Discovery image of Orcus taken in 2004[18]

Orcus was discovered on 17 February 2004, by American astronomers Michael Brown of Caltech, Chad Trujillo of the Gemini Observatory, and David Rabinowitz of Yale University. Precovery images taken by the Palomar Observatory as early as 8 November 1951 were later obtained from the Digitized Sky Survey.[2]

Name and symbol

The minor planet Orcus was named after one of the Roman gods of the underworld, Orcus. While Pluto (of Greek origin) was the ruler of the underworld, Orcus (of Etruscan origin) was a punisher of the condemned. The name was published by the Minor Planet Center on 26 November 2004 (M.P.C. 53177).[19] Under the guidelines of the International Astronomical Union's (IAU) naming conventions, objects with a similar size and orbit to that of Pluto are named after underworld deities. Accordingly, the discoverers suggested naming the object after Orcus, the Etruscan god of the underworld and punisher of broken oaths. The name was also a private reference to the homonymous Orcas Island, where Brown's wife had lived as a child and that they visit frequently.[20]

On 30 March 2005, Orcus's moon, Vanth, was named after a winged female demon, Vanth, of the Etruscan underworld. She could be present at the moment of death, and frequently acted as a psychopomp, a guide of the deceased to the underworld.[21]

Planetary symbols are no longer much used in astronomy, so Orcus never received a symbol in the astronomical literature. An Orcus symbol ( ), mostly used among astrologers,[22] is included in Unicode as U+1F77F.[23] The symbol was designed by Denis Moskowitz, a software engineer in Massachusetts; it is an OR monogram, designed to resemble both a skull and an orca's gape.[24] There is a rarer symbol  , an inverted astrological Pluto symbol, reflecting Orcus as the anti-Pluto: it was designed by Melanie Reinhart.[22]

Orbit and rotation

Orcus is in a 2:3 orbital resonance with Neptune, having an orbital period of 245 years,[4][1] and is classified as a plutino.[2] Its orbit is moderately inclined at 20.6 degrees to the ecliptic.[1] Orcus's orbit is similar to Pluto's (both have perihelia above the ecliptic), but is oriented differently. Although at one point its orbit approaches that of Neptune, the resonance between the two bodies means that Orcus itself is always a great distance away from Neptune (there is always an angular separation of over 60 degrees between them). Over a 14,000-year period, Orcus stays more than 18 AU from Neptune.[16] Because their mutual resonance with Neptune constrains Orcus and Pluto to remain in opposite phases of their otherwise very similar motions, Orcus is sometimes described as the "anti-Pluto".[17] Orcus last reached its aphelion (farthest distance from the Sun) in 2019 and will come to perihelion (closest distance to the Sun) around 9 January 2143.[9] Simulations by the Deep Ecliptic Survey show that over the next 10 million years Orcus may acquire a perihelion distance (qmin) as small as 27.8 AU.[4]

The rotation period of Orcus is uncertain, as different photometric surveys have produced different results. Some show low amplitude variations with periods ranging from 7 to 21 hours, whereas others show no variability.[25] The rotational axis of Orcus probably coincides with the orbital axis of its moon, Vanth. This means that Orcus is currently viewed pole-on, which could explain the near absence of any rotational modulation of its brightness.[25][26] Astronomer José Luis Ortiz and colleagues have derived a possible rotation period of about 10.5 hours, assuming that Orcus is not tidally locked with Vanth.[26] If, however, the primary is tidally locked with the satellite, the rotational period would coincide with the 9.7-day orbital period of Vanth.[26]

 
Mean-motion resonance of Orcus (rotating frame with a period equal to Neptune's orbital period)
 
The orbits of Orcus (blue), Pluto (red) and Neptune (grey). Orcus and Pluto are shown in the April 2006 positions. The dates of their perihelia (q) and aphelia (Q) are also marked.

Physical characteristics

Size and magnitude

 
Orcus compared to Earth and the Moon
 
Long-exposure photograph of Orcus at visual magnitude 19.2

The absolute magnitude of Orcus is approximately 2.3.[11] The detection of Orcus by the Spitzer Space Telescope in the far infrared[27] and by Herschel Space Telescope in submillimeter estimates its diameter at 958.4 km (595.5 mi), with an uncertainty of 22.9 km (14.2 mi).[11] Orcus appears to have an albedo of about 21–25 percent,[11] which may be typical of trans-Neptunian objects approaching the 1,000 km (620 mi) diameter range.[28] The magnitude and size estimates were made under the assumption that Orcus is a singular object. The presence of a relatively large satellite, Vanth, may change them considerably. The absolute magnitude of Vanth is estimated at 4.88, which means that it is about 11 times fainter than Orcus itself.[15] The ALMA submillimeter measurements taken in 2016 showed that Vanth has a relatively large size of 475 km (295 mi) with albedo of about 8 percent while Orcus's has a slightly smaller size of 910 km (570 mi).[10] Using a stellar occultation by Vanth in 2017, Vanth's diameter has been determined to be 442.5 km (275.0 mi), with an uncertainty of 10.2 km (6.3 mi).[29] Michael Brown's website lists Orcus as a dwarf planet with "near certainty",[30] Tancredi concludes that it is one,[31] and is massive enough to be considered one under the 2006 draft proposal of the IAU,[32] but the IAU has not formally recognized it as such.[33][34]

Mass and density

Orcus and Vanth are known to constitute a binary system. The mass of the system has been estimated to be (6.348±0.019)×1020 kg,[6] approximately equal to that of the Saturnian moon Tethys (6.175×1020 kg).[35] The mass of the Orcus system is about 3.8 percent that of Eris, the most-massive known dwarf planet (1.66×1022 kg).[15][36] How this mass is partitioned between Orcus and Vanth depends on their relative densities. If Vanth were 0.8 g/cm3 (typical for a TNO in this size range), it would be about 5% of Orcus's mass; if it had the same density of Orcus (that is, the system density of 1.53 g/cm3), then it would be about 20% of Orcus's mass. The low albedo of Vanth compared to Orcus suggests that their compositions are different and that Vanth's density is relatively low. Thus, the mass of Orcus is likely to be close to the system mass.[10][29]

Spectra and surface

EarthMoonCharonCharonNixNixKerberosKerberosStyxStyxHydraHydraPlutoPlutoDysnomiaDysnomiaErisErisNamakaNamakaHi'iakaHi'iakaHaumeaHaumeaMakemakeMakemakeMK2MK2XiangliuXiangliuGonggongGonggongWeywotWeywotQuaoarQuaoarSednaSednaVanthVanthOrcusOrcusActaeaActaeaSalaciaSalacia2002 MS42002 MS4 
Artistic comparison of Pluto, Eris, Haumea, Makemake, Gonggong, Quaoar, Sedna, Orcus, Salacia, 2002 MS4, and Earth along with the Moon

The first spectroscopic observations in 2004 showed that the visible spectrum of Orcus is flat (neutral in color) and featureless, whereas in the near-infrared there were moderately strong water absorption bands at 1.5 and 2.0 μm.[37] The neutral visible spectrum and strong water absorption bands of Orcus showed that Orcus appeared different from other trans-Neptunian objects, which typically have a red visible spectrum and often featureless infrared spectra.[37] Further infrared observations in 2004 by the European Southern Observatory and the Gemini telescope gave results consistent with mixtures of water ice and carbonaceous compounds, such as tholins.[13] The water and methane ices can cover no more than 50 percent and 30 percent of the surface, respectively.[38] This means the proportion of ice on the surface is less than on Charon, but similar to that on Triton.[38]

Later in 2008–2010 new infrared spectroscopic observations with a higher signal-to-noise ratio revealed additional spectral features. Among them are a deep water ice absorption band at 1.65 μm, which is an evidence of the crystalline water ice on the surface of Orcus, and a new absorption band at 2.22 μm. The origin of the latter feature is not completely clear. It can be caused either by ammonia/ammonium dissolved in the water ice or by methane/ethane ices.[12] The radiative transfer modeling showed that a mixture of water ice, tholins (as a darkening agent), ethane ice and ammonium ion (NH4+) provides the best match to the spectra, whereas a combination of water ice, tholins, methane ice and ammonia hydrate gives a slightly inferior result. On the other hand, a mixture of only ammonia hydrate, tholins and water ice failed to provide a satisfactory match.[25] So, as of 2010, the only reliably identified compounds on the surface of Orcus are crystalline water ice and, possibly, dark tholins. A firm identification of ammonia, methane and other hydrocarbons requires better infrared spectra.[25]

Orcus sits at the threshold for trans-Neptunian objects massive enough to retain volatiles such as methane on the surface.[25] The reflectance spectrum of Orcus shows the deepest water-ice absorption bands of any Kuiper belt object that is not associated with the Haumea collisional family.[15] The large icy satellites of Uranus have infrared spectra quite similar to that of Orcus.[15] Among other trans-Neptunian objects, the large plutino 2003 AZ84 and Pluto's moon Charon both have similar surface spectra to Orcus,[12] with flat, featureless visible spectra and moderately strong water ice absorption bands in the near-infrared.[25]

Cryovolcanism

Crystalline water ice on the surfaces of trans-Neptunian objects should be completely amorphized by the galactic and Solar radiation in about 10 million years.[12] Thus the presence of crystalline water ice, and possibly ammonia ice, may indicate that a renewal mechanism was active in the past on the surface of Orcus.[12] Ammonia so far has not been detected on any trans-Neptunian object or icy satellite of the outer planets other than Miranda.[12] The 1.65 μm band on Orcus is broad and deep (12%), as on Charon, Quaoar, Haumea, and icy satellites of giant planets.[12] Some calculations indicate that cryovolcanism, which is considered one of the possible renewal mechanisms, may indeed be possible for trans-Neptunian objects larger than about 1,000 km (620 mi).[25] Orcus may have experienced at least one such episode in the past, which turned the amorphous water ice on its surface into crystalline. The preferred type of volcanism may have been explosive aqueous volcanism driven by an explosive dissolution of methane from water–ammonia melts.[25]

Satellite

 
Orcus and Vanth imaged by Hubble in 2006
Main article: Vanth (moon)

Orcus has one known moon, Vanth (full designation (90482) Orcus I Vanth). It was discovered by Michael Brown and T.-A. Suer using discovery images taken by the Hubble Space Telescope on 13 November 2005.[39] The discovery was announced in an IAU Circular notice published on 22 February 2007.[40] A spatially resolved submillimeter imaging of Orcus–Vanth system in 2016 showed that Vanth has a relatively large size of 475 km (295 mi), with an uncertainty of 75 km (47 mi).[10] That estimate for Vanth is in good agreement with the size of about 442.5 km (275.0 mi) derived from a stellar occultation in 2017.[29] Like Charon compared to Pluto, Vanth is quite large compared to Orcus, and is one reason for characterizing Orcus as the 'anti-Pluto'. If Orcus is a dwarf planet, Vanth would be the third-largest known dwarf-planet moon, after Charon and Dysnomia. The ratio of masses of Orcus and Vanth is uncertain, possibly anywhere from 1:33 to 1:12.[41]

See also

References

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External links

 
Wikimedia Commons has media related to 90482 Orcus.
  • MPEC 2004-D09 announcing the discovery but attributing it to Raymond J. Bambery, Steven H. Pravdo, Michael D. Hicks, Kenneth J. Lawrence, Daniel MacDonald, Eleanor Helin and Robert Thicksten / NEAT
  • MPEC 2004-D13 correcting MPEC 2004-D09
  • Orcus of the Outer Solar System, Astronomy Picture of the Day, 25 March 2009
  • New world found far beyond Pluto, David Whitehouse, BBC News, 3 March 2004
  • A New Kuiper Belt Giant, Stuart Goldman, Sky & Telescope, 24 February 2004
  • 90482 Orcus at the JPL Small-Body Database
    • Close approach · Discovery · Ephemeris · Orbit diagram · Orbital elements · Physical parameters

January 07, 2023
90482, orcus, roman, orcus, mythology, other, uses, orcus, disambiguation, orcus, minor, planet, designation, provisional, designation, 2004, trans, neptunian, dwarf, planet, with, large, moon, vanth, diameter, surface, orcus, relatively, bright, with, albedo,. For the Roman god see Orcus mythology For other uses see Orcus disambiguation Orcus minor planet designation 90482 Orcus provisional designation 2004 DW is a trans Neptunian dwarf planet with a large moon Vanth 6 It has a diameter of 910 km 570 mi The surface of Orcus is relatively bright with albedo reaching 23 percent neutral in color and rich in water ice The ice is predominantly in crystalline form which may be related to past cryovolcanic activity Other compounds like methane or ammonia may also be present on its surface Orcus was discovered by American astronomers Michael Brown Chad Trujillo and David Rabinowitz on 17 February 2004 90482 OrcusOrcus and its moon Vanth imaged by the Hubble Space Telescope in 2006Discovery 1 2 Discovered byM E BrownC TrujilloD RabinowitzDiscovery date17 February 2004DesignationsMPC designation 90482 OrcusPronunciation ˈ ɔːr k e s 7 Named afterOrcus Roman mythology 3 Alternative designations2004 DWMinor planet categoryTNO 1 plutino 4 5 dwarf planet 6 AdjectivesOrcean ˈ ɔːr s i e n 8 Orbital characteristics 1 Epoch 31 May 2020 JD 2459000 5 Uncertainty parameter 2Observation arc68 16 yr 24 894 days Earliest precovery date8 November 1951Aphelion48 067 AU 7 1907 Tm Perihelion30 281 AU 4 5300 Tm Semi major axis39 174 AU 5 8603 Tm Eccentricity0 22701Orbital period sidereal 245 19 yr 89 557 days Mean anomaly181 735 Mean motion0 0m 14 472s dayInclination20 592 Longitude of ascending node268 799 Time of perihelion 9 January 2143 9 4 daysArgument of perihelion72 310 Known satellitesVanthPhysical characteristicsDimensions910 50 40 km 10 917 25 km 11 Mass 6 348 0 019 1020 kg system 6 Mean density1 53 0 15 0 13 g cm3 11 Equatorial surface gravity 0 2 m s2Equatorial escape velocity 0 43 km sGeometric albedo0 231 0 018 0 011 11 Temperature lt 44 K 12 Spectral type neutral 12 B V 0 68 13 V R 0 37 13 Apparent magnitude19 1 opposition 14 Absolute magnitude H 2 31 0 03 integral 11 2 41 0 05 15 Orcus is a plutino a trans Neptunian object that is locked in a 2 3 resonance with the ice giant Neptune making two revolutions around the Sun to every three of Neptune s 4 This is much like Pluto except that the phase of Orcus s orbit is opposite to Pluto s Orcus is at aphelion most recently in 2019 around when Pluto is at perihelion most recently in 1989 and vice versa 16 Orcus is the largest known plutino after Pluto itself The perihelion of Orcus s orbit is around 120 from that of Pluto while the eccentricities and inclinations are similar Because of these similarities and contrasts along with its large moon Vanth that recalls Pluto s large moon Charon Orcus has been regarded as the anti Pluto 17 This was a major consideration in selecting its name as the deity Orcus was the Roman Etruscan equivalent of the Roman Greek Pluto 17 Contents 1 History 1 1 Discovery 1 2 Name and symbol 2 Orbit and rotation 3 Physical characteristics 3 1 Size and magnitude 3 2 Mass and density 3 3 Spectra and surface 3 4 Cryovolcanism 4 Satellite 5 See also 6 References 7 External linksHistory EditDiscovery Edit Discovery image of Orcus taken in 2004 18 Orcus was discovered on 17 February 2004 by American astronomers Michael Brown of Caltech Chad Trujillo of the Gemini Observatory and David Rabinowitz of Yale University Precovery images taken by the Palomar Observatory as early as 8 November 1951 were later obtained from the Digitized Sky Survey 2 Name and symbol Edit The minor planet Orcus was named after one of the Roman gods of the underworld Orcus While Pluto of Greek origin was the ruler of the underworld Orcus of Etruscan origin was a punisher of the condemned The name was published by the Minor Planet Center on 26 November 2004 M P C 53177 19 Under the guidelines of the International Astronomical Union s IAU naming conventions objects with a similar size and orbit to that of Pluto are named after underworld deities Accordingly the discoverers suggested naming the object after Orcus the Etruscan god of the underworld and punisher of broken oaths The name was also a private reference to the homonymous Orcas Island where Brown s wife had lived as a child and that they visit frequently 20 On 30 March 2005 Orcus s moon Vanth was named after a winged female demon Vanth of the Etruscan underworld She could be present at the moment of death and frequently acted as a psychopomp a guide of the deceased to the underworld 21 Planetary symbols are no longer much used in astronomy so Orcus never received a symbol in the astronomical literature An Orcus symbol mostly used among astrologers 22 is included in Unicode as U 1F77F 23 The symbol was designed by Denis Moskowitz a software engineer in Massachusetts it is an OR monogram designed to resemble both a skull and an orca s gape 24 There is a rarer symbol an inverted astrological Pluto symbol reflecting Orcus as the anti Pluto it was designed by Melanie Reinhart 22 Orbit and rotation EditOrcus is in a 2 3 orbital resonance with Neptune having an orbital period of 245 years 4 1 and is classified as a plutino 2 Its orbit is moderately inclined at 20 6 degrees to the ecliptic 1 Orcus s orbit is similar to Pluto s both have perihelia above the ecliptic but is oriented differently Although at one point its orbit approaches that of Neptune the resonance between the two bodies means that Orcus itself is always a great distance away from Neptune there is always an angular separation of over 60 degrees between them Over a 14 000 year period Orcus stays more than 18 AU from Neptune 16 Because their mutual resonance with Neptune constrains Orcus and Pluto to remain in opposite phases of their otherwise very similar motions Orcus is sometimes described as the anti Pluto 17 Orcus last reached its aphelion farthest distance from the Sun in 2019 and will come to perihelion closest distance to the Sun around 9 January 2143 9 Simulations by the Deep Ecliptic Survey show that over the next 10 million years Orcus may acquire a perihelion distance qmin as small as 27 8 AU 4 The rotation period of Orcus is uncertain as different photometric surveys have produced different results Some show low amplitude variations with periods ranging from 7 to 21 hours whereas others show no variability 25 The rotational axis of Orcus probably coincides with the orbital axis of its moon Vanth This means that Orcus is currently viewed pole on which could explain the near absence of any rotational modulation of its brightness 25 26 Astronomer Jose Luis Ortiz and colleagues have derived a possible rotation period of about 10 5 hours assuming that Orcus is not tidally locked with Vanth 26 If however the primary is tidally locked with the satellite the rotational period would coincide with the 9 7 day orbital period of Vanth 26 Mean motion resonance of Orcus rotating frame with a period equal to Neptune s orbital period The orbits of Orcus blue Pluto red and Neptune grey Orcus and Pluto are shown in the April 2006 positions The dates of their perihelia q and aphelia Q are also marked Physical characteristics EditSize and magnitude Edit Orcus compared to Earth and the Moon Long exposure photograph of Orcus at visual magnitude 19 2 The absolute magnitude of Orcus is approximately 2 3 11 The detection of Orcus by the Spitzer Space Telescope in the far infrared 27 and by Herschel Space Telescope in submillimeter estimates its diameter at 958 4 km 595 5 mi with an uncertainty of 22 9 km 14 2 mi 11 Orcus appears to have an albedo of about 21 25 percent 11 which may be typical of trans Neptunian objects approaching the 1 000 km 620 mi diameter range 28 The magnitude and size estimates were made under the assumption that Orcus is a singular object The presence of a relatively large satellite Vanth may change them considerably The absolute magnitude of Vanth is estimated at 4 88 which means that it is about 11 times fainter than Orcus itself 15 The ALMA submillimeter measurements taken in 2016 showed that Vanth has a relatively large size of 475 km 295 mi with albedo of about 8 percent while Orcus s has a slightly smaller size of 910 km 570 mi 10 Using a stellar occultation by Vanth in 2017 Vanth s diameter has been determined to be 442 5 km 275 0 mi with an uncertainty of 10 2 km 6 3 mi 29 Michael Brown s website lists Orcus as a dwarf planet with near certainty 30 Tancredi concludes that it is one 31 and is massive enough to be considered one under the 2006 draft proposal of the IAU 32 but the IAU has not formally recognized it as such 33 34 Mass and density Edit Orcus and Vanth are known to constitute a binary system The mass of the system has been estimated to be 6 348 0 019 1020 kg 6 approximately equal to that of the Saturnian moon Tethys 6 175 1020 kg 35 The mass of the Orcus system is about 3 8 percent that of Eris the most massive known dwarf planet 1 66 1022 kg 15 36 How this mass is partitioned between Orcus and Vanth depends on their relative densities If Vanth were 0 8 g cm3 typical for a TNO in this size range it would be about 5 of Orcus s mass if it had the same density of Orcus that is the system density of 1 53 g cm3 then it would be about 20 of Orcus s mass The low albedo of Vanth compared to Orcus suggests that their compositions are different and that Vanth s density is relatively low Thus the mass of Orcus is likely to be close to the system mass 10 29 Spectra and surface Edit Artistic comparison of Pluto Eris Haumea Makemake Gonggong Quaoar Sedna Orcus Salacia 2002 MS4 and Earth along with the Moon vte The first spectroscopic observations in 2004 showed that the visible spectrum of Orcus is flat neutral in color and featureless whereas in the near infrared there were moderately strong water absorption bands at 1 5 and 2 0 mm 37 The neutral visible spectrum and strong water absorption bands of Orcus showed that Orcus appeared different from other trans Neptunian objects which typically have a red visible spectrum and often featureless infrared spectra 37 Further infrared observations in 2004 by the European Southern Observatory and the Gemini telescope gave results consistent with mixtures of water ice and carbonaceous compounds such as tholins 13 The water and methane ices can cover no more than 50 percent and 30 percent of the surface respectively 38 This means the proportion of ice on the surface is less than on Charon but similar to that on Triton 38 Later in 2008 2010 new infrared spectroscopic observations with a higher signal to noise ratio revealed additional spectral features Among them are a deep water ice absorption band at 1 65 mm which is an evidence of the crystalline water ice on the surface of Orcus and a new absorption band at 2 22 mm The origin of the latter feature is not completely clear It can be caused either by ammonia ammonium dissolved in the water ice or by methane ethane ices 12 The radiative transfer modeling showed that a mixture of water ice tholins as a darkening agent ethane ice and ammonium ion NH4 provides the best match to the spectra whereas a combination of water ice tholins methane ice and ammonia hydrate gives a slightly inferior result On the other hand a mixture of only ammonia hydrate tholins and water ice failed to provide a satisfactory match 25 So as of 2010 the only reliably identified compounds on the surface of Orcus are crystalline water ice and possibly dark tholins A firm identification of ammonia methane and other hydrocarbons requires better infrared spectra 25 Orcus sits at the threshold for trans Neptunian objects massive enough to retain volatiles such as methane on the surface 25 The reflectance spectrum of Orcus shows the deepest water ice absorption bands of any Kuiper belt object that is not associated with the Haumea collisional family 15 The large icy satellites of Uranus have infrared spectra quite similar to that of Orcus 15 Among other trans Neptunian objects the large plutino 2003 AZ84 and Pluto s moon Charon both have similar surface spectra to Orcus 12 with flat featureless visible spectra and moderately strong water ice absorption bands in the near infrared 25 Cryovolcanism Edit Crystalline water ice on the surfaces of trans Neptunian objects should be completely amorphized by the galactic and Solar radiation in about 10 million years 12 Thus the presence of crystalline water ice and possibly ammonia ice may indicate that a renewal mechanism was active in the past on the surface of Orcus 12 Ammonia so far has not been detected on any trans Neptunian object or icy satellite of the outer planets other than Miranda 12 The 1 65 mm band on Orcus is broad and deep 12 as on Charon Quaoar Haumea and icy satellites of giant planets 12 Some calculations indicate that cryovolcanism which is considered one of the possible renewal mechanisms may indeed be possible for trans Neptunian objects larger than about 1 000 km 620 mi 25 Orcus may have experienced at least one such episode in the past which turned the amorphous water ice on its surface into crystalline The preferred type of volcanism may have been explosive aqueous volcanism driven by an explosive dissolution of methane from water ammonia melts 25 Satellite Edit Orcus and Vanth imaged by Hubble in 2006 Main article Vanth moon Orcus has one known moon Vanth full designation 90482 Orcus I Vanth It was discovered by Michael Brown and T A Suer using discovery images taken by the Hubble Space Telescope on 13 November 2005 39 The discovery was announced in an IAU Circular notice published on 22 February 2007 40 A spatially resolved submillimeter imaging of Orcus Vanth system in 2016 showed that Vanth has a relatively large size of 475 km 295 mi with an uncertainty of 75 km 47 mi 10 That estimate for Vanth is in good agreement with the size of about 442 5 km 275 0 mi derived from a stellar occultation in 2017 29 Like Charon compared to Pluto Vanth is quite large compared to Orcus and is one reason for characterizing Orcus as the anti Pluto If Orcus is a dwarf planet Vanth would be the third largest known dwarf planet moon after Charon and Dysnomia The ratio of masses of Orcus and Vanth is uncertain possibly anywhere from 1 33 to 1 12 41 See also EditList of possible dwarf planets List of trans Neptunian objects List of Solar System objects by sizeReferences Edit a b c d e JPL Small Body Database Browser 90482 Orcus 2004 DW 2020 01 04 last obs Jet Propulsion Laboratory 29 January 2020 Retrieved 20 February 2020 a b c 90482 Orcus 2004 DW Minor Planet Center Retrieved 3 April 2017 Schmadel Lutz D 2006 90482 Orcus 39 5 0 22 20 5 Dictionary of Minor Planet Names 90482 Orcus Addendum to Fifth Edition 2003 2005 Springer Berlin Heidelberg p 236 doi 10 1007 978 3 540 34361 5 2818 ISBN 978 3 540 34361 5 a b c d Buie Marc W 22 December 2007 Orbit Fit and Astrometric record for 90482 SwRI Space Science Department Retrieved 19 September 2008 MPEC 2009 E53 Distant Minor Planets 2009 MAR 30 0 TT Minor Planet Center 11 March 2009 Retrieved 5 July 2011 a b c d Grundy Will M Noll Keith S Roe Henry G Buie Marc W Porter Simon B Parker Alex H Nesvorny David Levison Harold F Benecchi Susan D Stephens Denise C Trujillo Chad A 2019 Mutual Orbit Orientations of Transneptunian Binaries PDF Icarus 334 62 78 Bibcode 2019Icar 334 62G doi 10 1016 j icarus 2019 03 035 ISSN 0019 1035 Retrieved 2019 11 13 Orcus Dictionary com Unabridged Online n d Angley 1847 De Clifford the philosopher a b JPL Horizons Observer Location sun perihelion occurs when deldot changes from negative to positive a b c d Brown Michael E Butler Bryan J 22 January 2018 Medium sized satellites of large Kuiper belt objects The Astronomical Journal 156 4 164 arXiv 1801 07221 doi 10 3847 1538 3881 aad9f2 a b c d e f g Fornasier S Lellouch E Muller P T et al 2013 TNOs are Cool A survey of the trans Neptunian region VIII Combined Herschel PACS and SPIRE observations of 9 bright targets at 70 500 mm Astronomy amp Astrophysics 555 A92 arXiv 1305 0449v2 Bibcode 2013A amp A 555A 15F doi 10 1051 0004 6361 201321329 a b c d e f g h Barucci M A Merlin Guilbert Bergh Doressoundiram et al 2008 Surface composition and temperature of the TNO Orcus Astronomy and Astrophysics 479 1 L13 L16 Bibcode 2008A amp A 479L 13B doi 10 1051 0004 6361 20079079 a b c de Bergh C A Delsanti G P Tozzi E Dotto A Doressoundiram M A Barucci 2005 The Surface of the Transneptunian Object 9048 Orcus Astronomy amp Astrophysics 437 3 1115 1120 Bibcode 2005A amp A 437 1115D doi 10 1051 0004 6361 20042533 HORIZONS Web Interface JPL Solar System Dynamics Retrieved 2 July 2008 a b c d e Brown M E Ragozzine D Stansberry J Fraser W C 2010 The size density and formation of the Orcus Vanth system in the Kuiper belt The Astronomical Journal 139 6 2700 2705 arXiv 0910 4784 Bibcode 2010AJ 139 2700B doi 10 1088 0004 6256 139 6 2700 a b MPEC 2004 D15 2004 DW Minor Planet Center 20 February 2004 Retrieved 5 July 2011 a b c Michael E Brown 23 March 2009 S 2005 90482 1 needs your help Mike Brown s Planets blog Archived from the original on 28 March 2009 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6361 201014296 a b c Ortiz J L Cikota A Cikota S Hestroffer D Thirouin A Morales N Duffard R Gil Hutton R Santos Sanz P De La Cueva I 2010 A mid term astrometric and photometric study of trans Neptunian object 90482 Orcus Astronomy amp Astrophysics 525 A31 arXiv 1010 6187 Bibcode 2011A amp A 525A 31O doi 10 1051 0004 6361 201015309 Stansberry J Grundy W Brown M Cruikshank D Spencer J Trilling D Margot J L 2008 Physical Properties of Kuiper Belt and Centaur Objects Constraints from the Spitzer Space Telescope In M A Barucci H Boehnhardt D P Cruikshank A Morbidelli eds The Solar System Beyond Neptune Tucson University of Arizona Press pp 161 179 Bibcode 2008ssbn book 161S ISBN 978 0816527557 Wm Robert Johnston 17 September 2008 TNO Centaur diameters and albedos Johnston s Archive Archived from the original on 22 October 2008 Retrieved 17 October 2008 a b c Sickafoose A A Bosh A S Levine S E Zuluaga C A Genade A Schindler K Lister T A Person M J 21 October 2018 A stellar occultation by Vanth a satellite of 90482 Orcus Icarus 319 657 668 arXiv 1810 08977 Bibcode 2019Icar 319 657S doi 10 1016 j icarus 2018 10 016 Michael E Brown 23 Sep 2011 How many dwarf planets are there in the outer solar system updates daily California Institute of Technology Archived from the original on 18 October 2011 Retrieved 23 September 2011 Tancredi G Favre S 2008 Which are the dwarfs in the solar system PDF Asteroids Comets Meteors Retrieved 28 December 2007 Gingerich Owen 16 August 2006 The Path to Defining Planets PDF Harvard Smithsonian Center for Astrophysics and IAU EC Planet Definition Committee chair p 4 Retrieved 13 March 2007 Planetary Names Planet and Satellite Names and Discoverers Gazetteer of Planetary Nomenclature International Astronomical Union Working Group for Planetary System Nomenclature Retrieved 10 June 2012 NASA List of Dwarf Planets Archived from the original on 4 May 2012 Retrieved 9 June 2012 Jacobson R A Antreasian P G Bordi J J Criddle K E Ionasescu R Jones J B Mackenzie R A Meek M C Parcher D Pelletier F J Owen Jr W M Roth D C Roundhill I M Stauch J R December 2006 The Gravity Field of the Saturnian System from Satellite Observations and Spacecraft Tracking Data The Astronomical Journal 132 6 2520 2526 Bibcode 2006AJ 132 2520J doi 10 1086 508812 Brown Michael E Schaller Emily L 15 June 2007 The Mass of Dwarf Planet Eris PDF Science 316 5831 1585 Bibcode 2007Sci 316 1585B doi 10 1126 science 1139415 PMID 17569855 Archived from the original PDF on 4 March 2016 a b Fornasier S Dotto E Barucci M A Barbieri C 2004 Water ice on the surface of the large TNO 2004 DW Astronomy amp Astrophysics 422 2 L43 L46 Bibcode 2004A amp A 422L 43F doi 10 1051 0004 6361 20048004 a b Trujillo Chadwick A Brown Michael E Rabinowitz David L Geballe Thomas R 2005 Near Infrared Surface Properties of the Two Intrinsically Brightest Minor Planets 90377 Sedna and 90482 Orcus The Astrophysical Journal 627 2 1057 1065 arXiv astro ph 0504280 Bibcode 2005ApJ 627 1057T doi 10 1086 430337 Daniel W E Green 22 February 2007 IAUC 8812 Sats OF 2003 AZ 84 50000 55637 90482 International Astronomical Union Circular Retrieved 4 July 2011 Wm Robert Johnston 4 March 2007 90482 Orcus Johnston s Archive Retrieved 26 March 2009 Carry B Hestroffer D Demeo F E Thirouin A Berthier J Lacerda P Sicardy B Doressoundiram A Dumas C Farrelly D Muller T G 2011 Integral field spectroscopy of 90482 Orcus Vanth Astronomy amp Astrophysics 534 A115 arXiv 1108 5963 Bibcode 2011A amp A 534A 115C doi 10 1051 0004 6361 201117486 External links Edit Wikimedia Commons has media related to 90482 Orcus MPEC 2004 D09 announcing the discovery but attributing it to Raymond J Bambery Steven H Pravdo Michael D Hicks Kenneth J Lawrence Daniel MacDonald Eleanor Helin and Robert Thicksten NEAT MPEC 2004 D13 correcting MPEC 2004 D09 Chad Trujillo s page on 2004 DW Orcus of the Outer Solar System Astronomy Picture of the Day 25 March 2009 New world found far beyond Pluto David Whitehouse BBC News 3 March 2004 A New Kuiper Belt Giant Stuart Goldman Sky amp Telescope 24 February 2004 90482 Orcus at the JPL Small Body DatabaseClose approach Discovery Ephemeris Orbit diagram Orbital elements Physical parameters Portals Astronomy Stars Spaceflight Outer space Solar System Retrieved from https en wikipedia org w index php title 90482 Orcus amp oldid 1130432337, wikipedia, wiki, book, books, library,

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