Jump to content

Quaoar

This is a good article. Click here for more information.
From Wikipedia, the free encyclopedia
(Redirected from Atmosphere of Quaoar)

50000 Quaoar
Low-resolution Hubble Space Telescope image of Quaoar and its moon Weywot, February 2006
Discovery[1]
Discovered by
Discovery sitePalomar Observatory
Discovery date4 June 2002
Designations
(50000) Quaoar
Pronunciation/ˈkwɑːwɑːr/, /ˈkwɑː.ɑːr/
Named after
Qua-o-ar / Kwawar[2]
(deity of the Tongva people)
2002 LM60
AdjectivesQuaoarian
Symbol🝾 (mostly astrological)
Orbital characteristics[3]
Epoch 31 May 2020 (JD 2459000.5)
Uncertainty parameter 3
Observation arc65.27 yr (23,839 d)
Earliest precovery date25 May 1954
Aphelion45.488 AU (6.805 Tm)
Perihelion41.900 AU (6.268 Tm)
43.694 AU (6.537 Tm)
Eccentricity0.04106
288.83 yr (105,495 d)
301.104°
0° 0m 12.285s / day
Inclination7.9895°
188.927°
≈ 11 February 2075[6]
±17 days
147.480°
Known satellites1 (Weywot)
Physical characteristics
Dimensions1,286 × 1,080 × 932 km[a][7]
1,090±40 km (2024; volume equivalent)[7]
545±20 km (2024; volume equivalent)[7]
3.78×106 km2[8]
Volume6.78×108 km3[9]
Mass(1.20±0.05)×1021 kg[10]: 3 
Mean density
1.66–1.77 g/cm3[7]
Equatorial surface gravity
0.31 m/s2 at poles
to 0.16 m/s2 at longest axis
Equatorial escape velocity
0.59 km/s at poles
to 0.5 km/s at longest axis
17.6788±0.0004 h[11][10]
13.6°[b] or 14.0°[c] to ecliptic (if coplanar with rings)
North pole right ascension
258.47°±0.87°[10]: 3  or 259.82°±0.23°[13]: 4  (outer ring)
North pole declination
+54.14°±0.11°[10]: 3  or +53.45°±0.30°[13]: 4  (outer ring)
0.124±0.006[13]
Temperature≈ 44 K[14]
IR (moderately red)
B–V=0.94±0.01[15][16]
V−R=0.64±0.01[15]
V−I=1.28±0.02[16][17]
19.0[18]
2.737±0.008[18]
2.4 (assumed)[3][1]
40.4±1.8 milliarcseconds[19]

Quaoar (minor-planet designation: 50000 Quaoar) is a large, ringed dwarf planet in the Kuiper belt, a region of icy planetesimals beyond Neptune. It has an elongated ellipsoidal shape with an average diameter of 1,090 km (680 mi), about half the size of the dwarf planet Pluto. The object was discovered by American astronomers Chad Trujillo and Michael Brown at the Palomar Observatory on 4 June 2002. Quaoar's surface contains crystalline water ice and ammonia hydrate, which suggests that it might have experienced cryovolcanism. A small amount of methane is present on its surface, which can only be retained by the largest Kuiper belt objects.

Quaoar has one known moon, Weywot, which was discovered by Brown in February 2007.[20] Both objects were named after mythological figures from the Native American Tongva people in Southern California. Quaoar is the Tongva creator deity and Weywot is his son. In 2023, astronomers announced the discovery of two thin rings orbiting Quaoar outside its Roche limit, which defies theoretical expectations that rings outside the Roche limit should not be stable.[13]

History

[edit]

Discovery

[edit]
Quaoar was discovered using the Samuel Oschin telescope at Palomar Observatory
Animation of three discovery images taken over a period of 4.5 hours, showing the slow movement of Quaoar (indicated by the arrow)[21]

Quaoar was discovered on 4 June 2002 by American astronomers Chad Trujillo and Michael Brown at the Palomar Observatory in the Palomar Mountain Range in San Diego County, California.[1] The discovery formed part of the Caltech Wide Area Sky Survey, which was designed to search for the brightest Kuiper belt objects using the Palomar Observatory's 1.22-meter Samuel Oschin telescope.[22] Quaoar was first identified in images by Trujillo on 5 June 2002, when he noticed a dim, 18.6-magnitude object slowly moving among the stars of the constellation Ophiuchus.[23][24] Quaoar appeared relatively bright for a distant object, suggesting that it could have a size comparable to the diameter of Pluto.[25]

To ascertain Quaoar's orbit, Brown and Trujillo initiated a search for archival precovery images. They obtained several precovery images taken by the Near-Earth Asteroid Tracking survey from various observatories in 1996 and 2000–2002.[21] In particular, they had also found two archival photographic plates taken by astronomer Charles T. Kowal in May 1983,[24] who at the time was searching for the hypothesized Planet X at the Palomar Observatory.[26][27] From these precovery images, Brown and Trujillo were able to calculate Quaoar's orbit and distance. Additional precovery images of Quaoar have been later identified, with the earliest known found by Edward Rhoads on a photographic plate imaged on 25 May 1954 from the Palomar Observatory Sky Survey.[1][3]

Before announcing the discovery of Quaoar, Brown had planned to conduct follow-up observations using the Hubble Space Telescope to measure Quaoar's size.[28] He had also planned to announce the discovery as soon as possible and found it necessary to keep the discovery information confidential during the follow-up observations.[29] Rather than submitting his Hubble proposal under peer review, Brown submitted his proposal directly to one of Hubble's operators, who promptly allocated time to Brown.[29][30] While setting up the observing algorithm for Hubble, Brown had also planned to use one of the Keck telescopes in Mauna Kea, Hawaii, as a part of a study on cryovolcanism on the moons of Uranus.[29] This provided him additional time for follow-up observations and took advantage of the whole observing session in July to analyze Quaoar's spectrum and characterize its surface composition.[31][29]

The discovery of Quaoar was formally announced by the Minor Planet Center in a Minor Planet Electronic Circular on 7 October 2002.[24] It was given the provisional designation 2002 LM60, indicating that its discovery took place during the first half of June 2002.[24][32] Quaoar was the 1,512th object discovered in the first half of June, as indicated by the preceding letter and numbers in its provisional designation.[d] On that same day, Trujillo and Brown reported their scientific results from observations of Quaoar at the 34th annual meeting of the American Astronomical Society's Division for Planetary Sciences in Birmingham, Alabama. They announced Quaoar was the largest Kuiper belt object found yet, surpassing previous record holders 20000 Varuna and 2002 AW197.[22][28] Quaoar's discovery has been cited by Brown as having contributed to the reclassification of Pluto as a dwarf planet.[29] Since then, Brown has contributed to the discovery of larger trans-Neptunian objects, including Haumea, Eris, Makemake and Gonggong.

Name and symbol

[edit]

Upon Quaoar's discovery, it was initially given the temporary nickname "Object X" as a reference to Planet X, due to its potentially large size and unknown nature.[29] At the time, Quaoar's size was uncertain, and its high brightness led the discovery team to speculate that it may be a possible tenth planet. After measuring Quaoar's size with the Hubble Space Telescope in July, the team began considering names for the object, particularly those from local Native American mythologies.[29] Following the International Astronomical Union's (IAU) naming convention for minor planets, non-resonant Kuiper belt objects are to be named after creation deities.[32] The team settled on the name Kwawar, the creator god of the Tongva people indigenous to the Los Angeles Basin, where Brown's institute, the California Institute of Technology, was located.[26]

According to Brown, the name "Quaoar" is pronounced with three syllables, and Trujillo's website on Quaoar gives a three-syllable pronunciation, /ˈkwɑː.(w)ɑːr/, as an approximation of the Tongva pronunciation [ˈkʷaʔuwar].[23] The name can be also pronounced as two syllables, /ˈkwɑːwɑːr/, reflecting the usual English spelling and pronunciation of the deity Kwawar.[28][33][34]

In Tongva mythology, Kwawar is the genderless[33] creation force of the universe, singing and dancing deities into existence.[2] He first sings and dances to create Weywot (Sky Father), then they together sing Chehooit (Earth Mother) and Tamit (Grandfather Sun) into existence. As they did this, the creation force became more complex as each new deity joined the singing and dancing. Eventually, after reducing chaos to order, they created the seven great giants that upheld the world,[23][28] then the animals and finally the first man and woman, Tobohar and Pahavit.[23]

Upon their investigation of names from Tongva mythology, Brown and Trujillo realized that there were contemporary members of the Tongva people, whom they contacted for permission to use the name.[29] They consulted tribal historian Marc Acuña, who confirmed that the name Kwawar would indeed be an appropriate name for the newly discovered object.[23][33] However, the Tongva preferred the spelling Qua-o-ar, which Brown and Trujillo adopted, though with the hyphens omitted.[29] The name and discovery of Quaoar were publicly announced in October, though Brown had not sought approval of the name by the IAU's Committee on Small Body Nomenclature (CSBN).[29] Indeed, Quaoar's name was announced before the official numbering of the object, which Brian Marsden—the head of the Minor Planet Center—remarked in 2004 to be a violation of the protocol.[29][35] Despite this, the name was approved by the CSBN, and the naming citation, along with Quaoar's official numbering, was published in a Minor Planet Circular on 20 November 2002.[36]

Quaoar was given the minor planet number 50000, which was not by coincidence but to commemorate its large size, being that it was found in the search for a Pluto-sized object in the Kuiper belt.[36] The large Kuiper belt object 20000 Varuna was similarly numbered for a similar occasion.[37] However, subsequent even larger discoveries such as 136199 Eris were simply numbered according to the order in which their orbits were confirmed.[32]

The usage of planetary symbols is no longer recommended in astronomy, so Quaoar never received a symbol in the astronomical literature. A symbol 🝾, used mostly among astrologers,[38] is included in Unicode as U+1F77E.[39] The symbol was designed by Denis Moskowitz, a software engineer in Massachusetts; it combines the letter Q (for 'Quaoar') with a canoe, and is stylized to recall angular Tongva rock art.[40]

Orbit and classification

[edit]
Ecliptic view of Quaoar's orbit (blue) compared to Pluto (red) and Neptune (white). The approximate perihelion (q) and aphelion (Q) dates are marked for their respective orbits.
Polar view of Quaoar's orbit (yellow) along with various other large Kuiper belt objects

Quaoar orbits the Sun at an average distance of 43.7 AU (6.54 billion km; 4.06 billion mi), taking 288.8 years to complete one full orbit around the Sun. With an orbital eccentricity of 0.04, Quaoar follows a nearly circular orbit, only slightly varying in distance from 42 AU at perihelion to 45 AU at aphelion.[3] At such distances, light from the Sun takes more than 5 hours to reach Quaoar.[23] Quaoar has last passed aphelion in late 1932 and is currently approaching the Sun at a rate of 0.035 AU per year, or about 170 meters per second (380 mph).[41] Quaoar will reach perihelion around February 2075.[6]

Because Quaoar has a nearly circular orbit, it does not approach close to Neptune such that its orbit can become significantly perturbed under the gravitational influence of Neptune.[4] Quaoar's minimum orbit intersection distance from Neptune is only 12.3 AU—it does not approach Neptune within this distance over the course of its orbit, as it is not in a mean-motion orbital resonance with Neptune.[1][4] Simulations by the Deep Ecliptic Survey show that the perihelion and aphelion distances of Quaoar's orbit do not change significantly over the next ten million years; Quaoar's orbit appears to be stable over the long term.[4]

Quaoar is a trans-Neptunian object.[3] It is classified as a distant minor planet by the Minor Planet Center.[1] Because Quaoar is not in a mean-motion resonance with Neptune, it is also classified as a classical Kuiper belt object (cubewano) by the Minor Planet Center and Deep Ecliptic Survey.[4][5] Quaoar's orbit is moderately inclined to the ecliptic plane by 8 degrees, relatively high when compared to the inclinations of Kuiper belt objects within the dynamically cold population.[29][42] Because Quaoar's orbital inclination is greater than 4 degrees, it is part of the dynamically hot population of high-inclination classical Kuiper belt objects.[42] The high inclinations of hot classical Kuiper belt objects such as Quaoar are thought to have resulted from gravitational scattering by Neptune during its outward migration in the early Solar System.[43]

Physical characteristics

[edit]

Size and shape

[edit]
History of diameter estimates for Quaoar
Year Diameter (km) Method Refs
2004 1,260±190 imaging [19]
2007 844+207
−190
thermal [44]
2010 890±70 thermal/imaging [45]
2013 1,074±138 thermal [46]
2013 1,110±5 occultation [47]
2023 1,086±4 occultation [13]
2024 1,090±40 thermal/occultation [7]

As of 2024, measurements of Quaoar's shape from its rotational light curve and stellar occultations show that Quaoar is a triaxial ellipsoid with an average diameter of 1,090 km (680 mi).[7] Quaoar's diameter is roughly half that of Pluto and is slightly smaller than Pluto's moon Charon.[29] At the time of its discovery in 2002, Quaoar was the largest object found in the Solar System since the discovery of Pluto.[29] Quaoar was also the first trans-Neptunian object to be measured directly from Hubble Space Telescope images.[19]

Quaoar's far-infrared thermal emission and brightness in visible light both vary significantly (visible light curve amplitude 0.12–0.16 magnitudes) as Quaoar rotates every 17.68 hours, which most likely indicates Quaoar is elongated along its equator.[7] A 2024 analysis of Quaoar's visible and far-infrared rotational light curve by Csaba Kiss and collaborators determined that the lengths of Quaoar's equatorial axes differ by 19% (a/b = 1.19) and the lengths of Quaoar's polar and shortest equatorial axis differ by 16% (b/c = 1.16), which corresponds to ellipsoid dimensions of 1,286 km × 1,080 km × 932 km (799 mi × 671 mi × 579 mi).[a][7] The ellipsoidal shape of Quaoar matches the size and shape measurements from previous stellar occultations, and also explains why the size and shape of Quaoar appeared to change in these occultations.[7]: 6 

Diagram showing three mutually orthogonal views of Quaoar's ellipsoidal shape

Quaoar's elongated shape contradicts theoretical expectations that it should be in hydrostatic equilibrium, because of its large size and slow rotation.[7]: 10  According to Michael Brown, rocky bodies around 900 km (560 mi) in diameter should relax into hydrostatic equilibrium, whereas icy bodies relax into hydrostatic equilibrium somewhere between 200 km (120 mi) and 400 km (250 mi).[48] Slowly-rotating objects in hydrostatic equilibrium are expected to be oblate spheroids (Maclaurin spheroids), whereas rapidly-rotating objects in hydrostatic equilibrium, such as Haumea which rotates in nearly 4 hours, are expected to be flattened and elongated ellipsoids (Jacobi ellipsoids).[7]: 10  To explain Quaoar's non-equilibrium shape, Kiss and collaborators hypothesized that Quaoar originally had a rapid rotation and was in hydrostatic equilibrium, but its shape became "frozen in" and did not change as Quaoar spun down due to tidal forces from its moon Weywot.[7]: 10  This would resemble the situation of Saturn's moon Iapetus, which is too oblate for its current rotation rate.[49]

Mass and density

[edit]
Quaoar compared to the Earth and the Moon

Quaoar has a mass of 1.2×1021 kg, which was determined from Weywot's orbit using Kepler's third law.[13] Measurements of Quaoar's diameter and mass as of 2024 indicate it has a density between 1.66–1.77 g/cm3, which suggests its interior is composed of roughly 70% rock and 30% ice with low porosity.[7]: 10–11  Quaoar's density was previously thought to be much higher, between 2–4 g/cm3, because early measurements inaccurately suggested that Quaoar had a smaller diameter and a higher mass.[7]: 10  These early high-density estimates for Quaoar led researchers to hypothesize that the object might be a rocky planetary core exposed by a large impact event, but these hypotheses have since become obsolete as newer estimates indicate a lower density for Quaoar.[45]: 1550 [7]: 10 

Surface

[edit]

Quaoar has a dark surface that reflects about 12% of the visible light it receives from the Sun.[13] This may indicate that fresh ice has disappeared from Quaoar's surface.[45] The surface is moderately red, meaning that Quaoar reflects longer (redder) wavelengths of light more than shorter (bluer) wavelengths.[50] Many Kuiper belt objects such as 20000 Varuna and 28978 Ixion share a similar moderately red color.

Spectroscopic observations by David Jewitt and Jane Luu in 2004 revealed signs of crystalline water ice and ammonia hydrate on Quaoar's surface. These substances are expected to gradually break down due to solar and cosmic radiation, and crystalline water ice can only form in warm temperatures of at least 110 K (−163 °C), so the presence of crystalline water ice on Quaoar's surface indicates that it was heated to this temperature sometime in the last ten million years.[50]: 731  For context, Quaoar's present-day surface temperature is less than 50 K (−223.2 °C).[50]: 732  Jewitt and Luu proposed two hypotheses for Quaoar's heating, which are impact events and radiogenic heating.[50]: 731  The latter hypothesis allows for the possibility of cryovolcanism on Quaoar, which is supported by the presence of ammonia hydrate on Quaoar's surface.[50]: 733  Ammonia hydrate is believed to be cryovolcanically deposited onto Quaoar's surface.[50]: 733  A 2006 study by Hauke Hussmann and collaborators suggested that radiogenic heating alone may not be capable of sustaining an internal ocean of liquid water at Quaoar's mantle–core boundary.[51]

More precise observations of Quaoar's near infrared spectrum in 2007 indicated the presence of small quantities (5%) of solid methane and ethane. Given its boiling point of 112 K (−161 °C), methane is a volatile ice at average surface temperatures of Quaoar, unlike water ice or ethane. Both models and observations suggest that only a few larger bodies (Pluto, Eris and Makemake) can retain the volatile ices whereas the dominant population of small trans-Neptunian objects lost them. Quaoar, with only small amounts of methane, appears to be in an intermediary category.[31]

In 2022, low-resolution near-infrared (0.7–5 μm) spectroscopic observations by the James Webb Space Telescope (JWST) revealed the presence of carbon dioxide ice, complex organics, and significant amounts of ethane ice on Quaoar's surface. Other possible chemical compounds include hydrogen cyanide and carbon monoxide.[52]: 4  JWST also took medium-resolution near-infrared spectra of Quaoar and found evidence of small amounts of methane on Quaoar's surface. However, both JWST's low- and medium-resolution spectra of Quaoar did not show conclusive signs of ammonia hydrates.[52]: 10 

Possible atmosphere

[edit]

The presence of methane and other volatiles on Quaoar's surface suggest that it may support a tenuous atmosphere produced from the sublimation of volatiles.[14] With a measured mean temperature of approximately 44 K (−229.2 °C), the upper limit of Quaoar's atmospheric pressure is expected to be in the range of a few microbars.[14] Due to Quaoar's small size and mass, the possibility of Quaoar having an atmosphere of nitrogen and carbon monoxide has been ruled out, since the gases would escape from Quaoar.[14] The possibility of a methane atmosphere, with the upper limit being less than 1 microbar,[47][14] was considered until 2013, when Quaoar occulted a 15.8-magnitude star and revealed no sign of a substantial atmosphere, placing an upper limit to at least 20 nanobars, under the assumption that Quaoar's mean temperature is 42 K (−231.2 °C) and that its atmosphere consists of mostly methane.[47][14] The upper limit of atmosphere pressure was tightened to 10 nanobars after another stellar occultation in 2019.[53]

Satellite

[edit]
Artist's impression of Quaoar with its ring and its moon Weywot

Quaoar has one known moon, Weywot (full designation (50000) Quaoar I Weywot), discovered in 2006 and named after the sky god Weywot, son of Quaoar.[20][54] It orbits Quaoar at distance of about 13,300 km and is thought to be approximately 170 km (110 mi) in diameter.[55]

Rings

[edit]

Discovery

[edit]
Light curve graph of a star's brightness as seen by the Gemini North Observatory during the 9 August 2022 occultation by Quaoar and its two rings. The asymmetry of the outer Q1R ring's opacity is apparent from its differing brightness dips before and after the occultation by Quaoar at the center.

Besides accurately determining sizes and shapes, stellar occultation campaigns were planned on a long-term basis to search for rings and/or atmospheres around small bodies of the outer solar system. These campaigns agglomerated efforts of various teams in France, Spain and Brazil and were conducted under the umbrella of the European Research Council project Lucky Star.[10] The discovery of Quaoar's first known ring, Q1R, involved various instruments used during stellar occultations observed between 2018 and 2021: the robotic ATOM telescope of the High Energy Stereoscopic System (HESS) in Namibia, the 10.4-m Gran Telescopio Canarias (La Palma Island, Spain); the ESA CHEOPS space telescope, and several stations run by citizen astronomers in Australia where a report of a Neptune-like ring originated and a dense arc in Q1R was first observed.[10][56][57] Taken together, these observations reveal the presence of a partly dense, mostly tenuous and uniquely distant ring around Quaoar, a discovery announced in February 2023.[10][56]

In April 2023, astronomers of the Lucky Star project published the discovery of another ring of Quaoar, Q2R.[13] The Q2R ring was detected by the highly-sensitive 8.2-m Gemini North and the 4.0-m Canada-France-Hawaii Telescope in Mauna Kea, Hawaii, during an observing campaign to confirm Quaoar's Q1R ring in a stellar occultation on 9 August 2022.[13] Quaoar is the fourth minor planet known and confirmed to have a ring system, after 10199 Chariklo, 2060 Chiron, and Haumea.[10][e]

Properties

[edit]
Orbit diagrams of the Quaoar–Weywot system
Viewed from Earth
Viewed top-down over Quaoar's north pole

Quaoar possesses two narrow rings, provisionally named Q1R and Q2R by order of discovery, which are confined at radial distances where their orbital periods are integer ratios of Quaoar's rotational period. That is, the rings of Quaoar are in spin-orbit resonances.[13]

Ring–moon system data[13]
Rings
Ring
designation
Radius
(km)
Width
(km)
Optical depth
(τ)
Q2R 2520±20 10 ≈0.004
Q1R 4057±6 5–300 0.004–0.7
Moon
Name Semi-major axis
(km)
Diameter
(km)
Period
(days)
Weywot 13289±189 170 12.4311±0.0015

The outer ring, Q1R, orbits Quaoar at a distance of 4,057 ± 6 km (2,521 ± 4 mi), over seven times the radius of Quaoar and more than double the theoretical maximum distance of the Roche limit.[13] The Q1R ring is not uniform and is strongly irregular around its circumference, being more opaque (and denser) where it is narrow and less opaque where it is broader.[10] The Q1R ring's radial width ranges from 5 to 300 km (3 to 200 mi) while its optical depth ranges from 0.004 to 0.7.[13] The irregular width of the Q1R ring resembles Saturn's frequently-perturbed F ring or Neptune's ring arcs, which may imply the presence of small, kilometer-sized moonlets embedded within the Q1R ring and gravitationally perturbing the material. The Q1R ring likely consists of icy particles that elastically collide with each other without accreting into a larger mass.[10]

Q1R is located in between the 6:1 mean-motion orbital resonance with Quaoar's moon Weywot at 4,021 ± 57 km (2,499 ± 35 mi) and Quaoar's 1:3 spin-orbit resonance at 4,197 ± 58 km (2,608 ± 36 mi). The Q1R ring's coincidental location at these resonances implies they play a key role in maintaining the ring without having it accrete into a single moon.[10] In particular, the confinement of rings to the 1:3 spin-orbit resonance may be common among ringed small Solar System bodies, as it has been previously seen in Chariklo and Haumea.[10]

The inner ring, Q2R, orbits Quaoar at a distance of 2,520 ± 20 km (1,566 ± 12 mi), about four and a half times Quaoar's radius and also outside Quaoar's Roche limit.[13] The Q2R ring's location coincides with Quaoar's 5:7 spin-orbit resonance at 2,525 ± 58 km (1,569 ± 36 mi). Compared to Q1R, the Q2R ring appears relatively uniform with a radial width of 10 km (6.2 mi). With an optical depth of 0.004, the Q2R ring is very tenuous and its opacity is comparable to the least dense part of the Q1R ring.[13]

Exploration

[edit]
Quaoar from New Horizons viewed at a distance of 14 AU

It has been calculated that a flyby mission to Quaoar using a Jupiter gravity assist would take 13.6 years, for launch dates of 25 December 2026, 22 November 2027, 22 December 2028, 22 January 2030 and 20 December 2040. Quaoar would be 41 to 43 AU from the Sun when the spacecraft arrived.[58] In July 2016, the Long Range Reconnaissance Imager (LORRI) aboard the New Horizons spacecraft took a sequence of four images of Quaoar from a distance of about 14 AU.[59] Interstellar Probe, a concept by Pontus Brandt and his colleagues at Johns Hopkins Applied Physics Laboratory would potentially fly by Quaoar in the 2030s before continuing to the interstellar medium, and the first of China National Space Administration's proposed Shensuo probe designed to explore the heliosphere has it considered as a potential flyby target.[60][61][62] Quaoar has been chosen as a flyby target for missions like these particularly for its escaping methane atmosphere and possible cryovolcanism, as well as its close proximity to the heliospheric nose.[60]

Notes

[edit]
  1. ^ a b Ellipsoidal dimensions in km is calculated from the volume equivalent diameter of 1,090 km, axial ratios of a/b = 1.19 and b/c = 1.16 given by Kiss et al. (2024),[7] and the formula for the volume of an ellipsoid, .
  2. ^ Morgado et al. (2023) give the outer ring's north pole direction in terms of equatorial coordinates (α, δ) = (258.47°, +54.14°), where α is right ascension and δ is declination.[10]: 3  Transforming these equatorial coordinates to ecliptic coordinates gives λ ≈ 240.17° and β ≈ +76.38°.[12] The ecliptic latitude, β, is the angular offset from the ecliptic plane, whereas inclination i with respect to the ecliptic is the angular offset from the ecliptic north pole at β = +90° ; i with respect to the ecliptic would be the complement of β, which is expressed by the difference i = 90° – β. Thus, the axial tilt of Quaoar's outer ring is 13.62° with respect to the ecliptic. If the outer ring is coplanar to Quaoar's equator (having the same north pole orientation), then Quaoar would have the same axial tilt with respect to the ecliptic.
  3. ^ Pereira et al. (2023) give the outer ring's north pole direction in terms of equatorial coordinates (α, δ) = (17h 19m 16s, +53° 27′), where α is right ascension and δ is declination.[13]: 4  Converting these equatorial coordinates from sexagesimal to decimal degrees gives (α, δ) = (259.82°, +53.45°). Then, transforming these equatorial coordinates to ecliptic coordinates gives λ ≈ 64.26° (ecliptic longitude) and β ≈ +75.98° (ecliptic latitude).[12] Subtracting this value of β from +90° gives the inclination of Quaoar's outer ring with respect to the ecliptic: i = 90° – β ≈ 14.02°. If the outer ring is coplanar to Quaoar's equator (having the same north pole orientation), then Quaoar would have the same axial tilt with respect to the ecliptic.
  4. ^ In the convention for minor planet provisional designations, the first letter represents the half-month of the year of discovery while the second letter and numbers indicate the order of discovery within that half-month. In the case for 2002 LM60, the first letter 'L' corresponds to the first half-month of June 2002 while the preceding letter 'M' indicates that it is the 12th object discovered on the 61st cycle of discoveries (with 60 cycles completed). Each completed cycle consists of 25 letters representing discoveries, hence 12 + (60 completed cycles × 25 letters) = 1,512.[32]
  5. ^ 2060 Chiron's rings were initially observed in 2011, and were confirmed by 2022

References

[edit]
  1. ^ a b c d e f g "50000 Quaoar (2002 LM60)". Minor Planet Center. International Astronomical Union. Archived from the original on 1 December 2017. Retrieved 30 November 2017.
  2. ^ a b Schmadel, Lutz D. (2006). "(50000) Quaoar". Dictionary of Minor Planet Names – (50000) Quaoar, Addendum to Fifth Edition: 2003–2005. Springer Berlin Heidelberg. p. 1197. doi:10.1007/978-3-540-29925-7. ISBN 978-3-540-00238-3. Archived from the original on 2 February 2020. Retrieved 7 December 2019.
  3. ^ a b c d e f "JPL Small-Body Database Browser: 50000 Quaoar (2002 LM60)" (31 August 2019 last obs.). Jet Propulsion Laboratory. 24 September 2019. Archived from the original on 9 April 2020. Retrieved 20 February 2020.
  4. ^ a b c d e Buie, M. W. "Orbit Fit and Astrometric record for 50000". Southwest Research Institute. Archived from the original on 29 January 2020. Retrieved 27 February 2018.
  5. ^ a b Marsden, Brian G. (17 July 2008). "MPEC 2008-O05 : Distant Minor Planets (2008 Aug. 2.0 TT)". Minor Planet Electronic Circular. Minor Planet Center. Archived from the original on 2 October 2018. Retrieved 27 February 2018.
  6. ^ a b JPL Horizons Archived 9 May 2021 at the Wayback Machine Observer Location: @sun (Perihelion occurs when deldot changes from negative to positive. Uncertainty in time of perihelion is 3-sigma.)
  7. ^ a b c d e f g h i j k l m n o p Kiss, C.; Müller, T. G.; Marton, G.; Szakáts, R.; Pál, A.; Molnár, L.; et al. (March 2024). "The visible and thermal light curve of the large Kuiper belt object (50000) Quaoar". Astronomy & Astrophysics. 684: A50. arXiv:2401.12679. Bibcode:2024A&A...684A..50K. doi:10.1051/0004-6361/202348054.
  8. ^ "Ellipsoid surface area: 3.78281×10^6 km2". WolframAlpha. Archived from the original on 11 March 2024. Retrieved 11 March 2024.
  9. ^ "Ellipsoid volume: 6.77765×10^8 km3". WolframAlpha. Archived from the original on 11 March 2024. Retrieved 11 March 2024.
  10. ^ a b c d e f g h i j k l m B. E. Morgado; et al. (8 February 2023). "A dense ring of the trans-Neptunian object Quaoar outside its Roche limit". Nature. 614 (7947): 239–243. Bibcode:2023Natur.614..239M. doi:10.1038/S41586-022-05629-6. ISSN 1476-4687. Wikidata Q116754015.
  11. ^ Ortiz, J. L.; Gutiérrez, P. J.; Casanova, V.; Teixeira, V. R. (October 2003). "Rotational brightness variations in Trans-Neptunian Object 50000 Quaoar" (PDF). Astronomy & Astrophysics. 409 (2): L13–L16. Bibcode:2003A&A...409L..13O. doi:10.1051/0004-6361:20031253. Archived (PDF) from the original on 12 May 2021. Retrieved 3 December 2019.
  12. ^ a b "Coordinate Transformation & Galactic Extinction Calculator". NASA/IPAC Extragalactic Database. California Institute of Technology. Archived from the original on 22 January 2023. Retrieved 11 February 2023. Equatorial → Ecliptic, J2000 for equinox and epoch. NOTE: When inputting equatorial coordinates, specify the units in the format "54.14d" instead of "54.14".
  13. ^ a b c d e f g h i j k l m n o p C. L. Pereira; et al. (2023). "The two rings of (50000) Quaoar". Astronomy & Astrophysics. arXiv:2304.09237. Bibcode:2023A&A...673L...4P. doi:10.1051/0004-6361/202346365. ISSN 0004-6361. Wikidata Q117802048.
  14. ^ a b c d e f Fraser, Wesley C.; Trujillo, Chad; Stephens, Andrew W.; Gimeno, German; Brown, Michael E.; Gwyn, Stephen; Kavelaars, J. J. (September 2013). "Limits on Quaoar's Atmosphere". The Astrophysical Journal Letters. 774 (2): 4. arXiv:1308.2230. Bibcode:2013ApJ...774L..18F. doi:10.1088/2041-8205/774/2/L18. S2CID 9122379.
  15. ^ a b Tegler, Stephen C. (1 February 2007). "Kuiper Belt Object Magnitudes and Surface Colors". Northern Arizona University. Archived from the original on 1 September 2006. Retrieved 27 February 2018.
  16. ^ a b Belskaya, Irina N.; Barucci, Maria A.; Fulchignoni, Marcello; Lazzarin, M. (April 2015). "Updated taxonomy of trans-neptunian objects and centaurs: Influence of albedo". Icarus. 250: 482–491. Bibcode:2015Icar..250..482B. doi:10.1016/j.icarus.2014.12.004.
  17. ^ "LCDB Data for (50000) Quaoar". Asteroid Lightcurve Database. Archived from the original on 3 October 2020. Retrieved 30 November 2017.
  18. ^ a b Grundy, Will (5 November 2019). "Quaoar and Weywot (50000 2002 LM60)". Lowell Observatory. Archived from the original on 25 March 2019. Retrieved 2 December 2019.
  19. ^ a b c Brown, Michael E.; Trujillo, Chadwick A. (April 2004). "Direct Measurement of the Size of the Large Kuiper Belt Object (50000) Quaoar" (PDF). The Astronomical Journal. 127 (4): 2413–2417. Bibcode:2004AJ....127.2413B. doi:10.1086/382513. S2CID 1877283. Archived (PDF) from the original on 7 January 2018. Retrieved 27 February 2018.
  20. ^ a b Green, Daniel W. E., ed. (22 February 2007). "Satellites of 2003 AZ_84, (50000), (55637), and (90482)". International Astronomical Union Circular. No. 8812. International Astronomical Union. Bibcode:2007IAUC.8812....1B. ISSN 0081-0304. Archived from the original on 19 July 2011.
  21. ^ a b Trujillo, Chad. "Quaoar Precoveries". www.chadtrujillo.com. Archived from the original on 6 December 2002. Retrieved 30 November 2017.
  22. ^ a b Trujillo, C. A.; Brown, M. E. (June 2003). "The Caltech Wide Area Sky Survey" (PDF). Earth, Moon, and Planets. 92 (1): L13–L16. Bibcode:2003EM&P...92...99T. doi:10.1023/B:MOON.0000031929.19729.a1. S2CID 189905639. Archived (PDF) from the original on 3 October 2020. Retrieved 9 January 2020.
  23. ^ a b c d e f Trujillo, Chad. "Frequently Asked Questions About Quaoar". physics.nau.edu. Northern Arizona University. Archived from the original on 11 February 2007. Retrieved 30 November 2017.
  24. ^ a b c d Marsden, Brian G. (7 October 2002). "MPEC 2002-T34 : 2002 LM60". Minor Planet Electronic Circular. Minor Planet Center. Archived from the original on 7 February 2019. Retrieved 8 January 2020.
  25. ^ "A Cold New World". NASA Science. NASA. 7 October 2002. Archived from the original on 20 December 2019. Retrieved 8 January 2020.
  26. ^ a b Nadin, Elisabeth (7 October 2002). "Caltech scientists find largest object in solar system since Pluto's discovery". Caltech Matters. California Institute of Technology. Archived from the original on 6 May 2020. Retrieved 8 January 2020.
  27. ^ Wilford, John Noble (8 October 2002). "Telescopes Find a Miniplanet At the Solar System's Edge". The New York Times. Archived from the original on 13 July 2020. Retrieved 8 January 2020.
  28. ^ a b c d "Hubble Spots an Icy World Far Beyond Pluto". HubbleSite. Space Telescope Science Institute. 7 October 2002. Archived from the original on 2 August 2007.
  29. ^ a b c d e f g h i j k l m n Brown, Michael E. (7 December 2010). "Chapter Five: An Icy Nail". How I Killed Pluto and Why It Had It Coming. Spiegel & Grau. pp. 63–85. ISBN 978-0-385-53108-5.
  30. ^ Brown, Michael E. (18 June 2002). "Direct Measurement of the Size of the Largest Kuiper Belt Object". Mikulski Archive for Space Telescopes. Space Telescope Science Institute: 9678. Bibcode:2002hst..prop.9678B. Archived from the original on 3 October 2020. Retrieved 8 January 2020.
  31. ^ a b Schaller, E. L.; Brown, M. E. (November 2007). "Detection of Methane on Kuiper Belt Object (50000) Quaoar". The Astrophysical Journal. 670 (1): L49–L51. arXiv:0710.3591. Bibcode:2007ApJ...670L..49S. doi:10.1086/524140. S2CID 18587369.
  32. ^ a b c d "How Are Minor Planets Named?". Minor Planet Center. International Astronomical Union. Archived from the original on 25 January 2021. Retrieved 5 January 2017.
  33. ^ a b c Street, Nick (August 2008). "Heavenly Bodies and the People of the Earth". Search Magazine. Heldref Publications. Archived from the original on 18 May 2009. Retrieved 8 January 2020.
  34. ^ NASA/JHUAPL/SwRI (2016) Quaoar Archived 18 March 2023 at the Wayback Machine
  35. ^ Marsden, Brian G. (28 September 2004). "MPEC 2004-S73 : Editorial Notice". Minor Planet Electronic Circular. Minor Planet Center. Archived from the original on 8 May 2020. Retrieved 8 January 2020.
  36. ^ a b "M.P.C. 47066" (PDF). Minor Planet Center. International Astronomical Union. 20 November 2002. Archived (PDF) from the original on 20 September 2021. Retrieved 4 December 2019.
  37. ^ "M.P.C. 41805" (PDF). Minor Planet Center. International Astronomical Union. 9 January 2001. Archived (PDF) from the original on 6 March 2012. Retrieved 15 March 2019.
  38. ^ Miller, Kirk (26 October 2021). "Unicode request for dwarf-planet symbols" (PDF). unicode.org. Archived (PDF) from the original on 23 March 2022. Retrieved 29 January 2022.
  39. ^ "Proposed New Characters: The Pipeline". Archived from the original on 29 January 2022. Retrieved 29 January 2022.
  40. ^ Anderson, Deborah (4 May 2022). "Out of this World: New Astronomy Symbols Approved for the Unicode Standard". unicode.org. The Unicode Consortium. Archived from the original on 6 August 2022. Retrieved 6 August 2022.
  41. ^ "Horizon Online Ephemeris System for 50000 Quaoar (2002 LM60)" ((Select Ephemeris Type: Observer, Observer Location: @sun, and Time Span: Start=1932-01-01, Step=1 d)). Jet Propulsion Laboratory. Archived from the original on 9 April 2020. Retrieved 24 January 2020.
  42. ^ a b Delsanti, Audrey; Jewitt, David (2006). "The Solar System Beyond The Planets" (PDF). In Blonde, P.; Mason, J. (eds.). Solar System Update. Springer. pp. 267–293. Bibcode:2006ssu..book..267D. doi:10.1007/3-540-37683-6_11. ISBN 3-540-26056-0. Archived from the original (PDF) on 25 September 2007.
  43. ^ Levison, Harold F.; Morbidelli, Alessandro; Van Laerhoven, Christa; Gomes, Rodney S.; Tsiganis, Kleomenis (July 2008). "Origin of the Structure of the Kuiper Belt during a Dynamical Instability in the Orbits of Uranus and Neptune". Icarus. 196 (1): 258–273. arXiv:0712.0553. Bibcode:2008Icar..196..258L. doi:10.1016/j.icarus.2007.11.035. S2CID 7035885.
  44. ^ Stansberry, John; Grundy, Will; Brown, Mike; Cruikshank, Dale; Spencer, John; Trilling, David; Margot, Jean-Luc (2008). "Physical Properties of Kuiper Belt and Centaur Objects: Constraints from the Spitzer Space Telescope" (PDF). The Solar System Beyond Neptune. University of Arizona Press. pp. 161–179. arXiv:astro-ph/0702538. Bibcode:2008ssbn.book..161S. ISBN 978-0-8165-2755-7. Archived (PDF) from the original on 21 September 2020. Retrieved 4 December 2019.
  45. ^ a b c Fraser, Wesley C.; Brown, Michael E. (May 2010). "Quaoar: A Rock in the Kuiper Belt". The Astrophysical Journal. 714 (2): 1547–1550. arXiv:1003.5911. Bibcode:2010ApJ...714.1547F. doi:10.1088/0004-637X/714/2/1547. S2CID 17386407.
  46. ^ Fornasier, S.; Lellouch, E.; Müller, T.; Santos-Sanz, P.; Panuzzo, P.; Kiss, C.; et al. (July 2013). "TNOs are Cool: A survey of the trans-Neptunian region. VIII. Combined Herschel PACS and SPIRE observations of nine bright targets at 70–500 μm". Astronomy & Astrophysics. 555 (A15): 22. arXiv:1305.0449v2. Bibcode:2013A&A...555A..15F. doi:10.1051/0004-6361/201321329. S2CID 119261700.
  47. ^ a b c Braga-Ribas, F.; Sicardy, B.; Ortiz, J. L.; Lellouch, E.; Tancredi, G.; Lecacheux, J.; et al. (August 2013). "The Size, Shape, Albedo, Density, and Atmospheric Limit of Transneptunian Object (50000) Quaoar from Multi-chord Stellar Occultations". The Astrophysical Journal. 773 (1): 13. Bibcode:2013ApJ...773...26B. doi:10.1088/0004-637X/773/1/26. hdl:11336/1641. S2CID 53724395. Archived from the original on 21 April 2022. Retrieved 29 April 2021.
  48. ^ Brown, Michael E. "The Dwarf Planets". California Institute of Technology. Archived from the original on 29 January 2008. Retrieved 27 February 2018.
  49. ^ Castillo-Rogez, J. C; Matson, D. L.; Sotin, C.; Johnson, T. V.; Lunine, J. I.; Thomas, P. C. (September 2007). "Iapetus' geophysics: Rotation rate, shape, and equatorial ridge". Icarus. 190 (1): 179–202. Bibcode:2007Icar..190..179C. doi:10.1016/j.icarus.2007.02.018.
  50. ^ a b c d e f Jewitt, David C.; Luu, Jane (December 2004). "Crystalline water ice on the Kuiper belt object (50000) Quaoar" (PDF). Nature. 432 (7018): 731–733. Bibcode:2004Natur.432..731J. doi:10.1038/nature03111. PMID 15592406. S2CID 4334385. Archived (PDF) from the original on 9 August 2017. Retrieved 14 April 2013.
  51. ^ Hussmann, Hauke; Sohl, Frank; Spohn, Tilman (November 2006). "Subsurface oceans and deep interiors of medium-sized outer planet satellites and large trans-neptunian objects". Icarus. 185 (1): 258–273. Bibcode:2006Icar..185..258H. doi:10.1016/j.icarus.2006.06.005.
  52. ^ a b Emery, J. P.; Wong, I.; Brunetto, R.; Cook, R.; Pinilla-Alonso, N.; Stansberry, J. A.; et al. (March 2024). "A Tale of 3 Dwarf Planets: Ices and Organics on Sedna, Gonggong, and Quaoar from JWST Spectroscopy". Icarus. 414 (116017). arXiv:2309.15230. Bibcode:2024Icar..41416017E. doi:10.1016/j.icarus.2024.116017.
  53. ^ Arimatsu, Ko; Ohsawa, Ryou; Hashimoto, George L.; Urakawa, Seitaro; Takahashi, Jun; Tozuka, Miyako; et al. (December 2019). "New constraint on the atmosphere of (50000) Quaoar from a stellar occultation". The Astronomical Journal. 158 (6): 7. arXiv:1910.09988. Bibcode:2019AJ....158..236A. doi:10.3847/1538-3881/ab5058. S2CID 204823847.
  54. ^ "Heavenly Bodies and the People of the Earth" Archived 5 January 2009 at archive.today, Nick Street, Search Magazine, July/August 2008
  55. ^ Kretlow, M. (January 2020). "Beyond Jupiter – (50000) Quaoar" (PDF). Journal for Occultation Astronomy. 10 (1): 24–31. Bibcode:2020JOA....10a..24K. Archived (PDF) from the original on 25 January 2020. Retrieved 9 January 2020.
  56. ^ a b "ESA's Cheops finds an unexpected ring around dwarf planet Quaoar". European Space Agency. 8 February 2023. Archived from the original on 8 February 2023. Retrieved 21 April 2023.
  57. ^ Hecht, Jeff (7 May 2023). "Second Ring Around Quaoar Puzzles Astronomers". Sky & Telescope. Archived from the original on 7 May 2023. Retrieved 7 May 2023.
  58. ^ McGranaghan, Ryan; Sagan, Brent; Dove, Gemma; Tullos, Aaron; Lyne, James E.; Emery, Joshua P. (September 2011). "A Survey of Mission Opportunities to Trans-Neptunian Objects". Journal of the British Interplanetary Society. 64: 296–303. Bibcode:2011JBIS...64..296M. Archived from the original on 29 January 2020. Retrieved 5 December 2019.
  59. ^ "New Horizons Spies a Kuiper Belt Companion". pluto.jhuapl.edu. Johns Hopkins University Applied Physics Laboratory. 31 August 2016. Archived from the original on 15 November 2017. Retrieved 7 September 2016.
  60. ^ a b Brandt, Pontus C.; McNutt, R.; Hallinan, G.; Shao, M.; Mewaldt, R.; Brown, M.; et al. (February 2017). The Interstellar Probe Mission: Humanity's First Explicit Step in Reaching Another Star (PDF). Planetary Science Vision 2050 Workshop. Lunar and Planetary Institute. Bibcode:2017LPICo1989.8173B. 8173. Archived (PDF) from the original on 13 March 2021. Retrieved 24 July 2018.
  61. ^ Runyon, K. D.; Mandt, K.; Stern, S. A.; Brandt, P. C.; McNutt, R. L. (December 2018). Kuiper Belt Planet Geoscience from Interstellar Probe. AGU Fall Meeting 2018. American Geophysical Union. Bibcode:2018AGUFMSH32C..10R. SH32C-10. Archived from the original on 3 October 2020. Retrieved 30 March 2019.
  62. ^ Jones, Andrew (16 April 2021). "China to launch a pair of spacecraft towards the edge of the solar system". SpaceNews. SpaceNews. Archived from the original on 29 September 2021. Retrieved 29 April 2021.
[edit]