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145452 Ritona

Classical Kuiper belt object

Field	Value
minorplanet	yes
background	#C2E0FF
name	145452 Ritona
image	Ritona Hubble 2010 north-up.png
caption	Ritona imaged by the Hubble Space Telescope on 25 April 2010
discovery_ref
discoverer	{{Ubl
discovery_site	Apache Point Obs.
discovered	10 September 2005
mpc_name	(145452) Ritona
alt_names
pronounced
named_after	Ritona
mp_category	{{Hlist
TNO<ref name	"jpldata"/
classical (hot)<ref name	"Vilenius2012"/
distant<ref name	"MPC-object"/
Scat-Ext<ref name	"Buie"/
orbit_ref
epoch	5 May 2025 (JD 2460800.5)
uncertainty	0
observation_arc	70.99 yr (25930 days)
earliest_precovery_date	2 June 1954
barycentric	yes
aphelion	42.450 AU
perihelion	40.575
time_periastron	≈ 15 June 2029
semimajor	41.512 AU
eccentricity	0.0226
period	267.29 yr (97,627 d)
mean_anomaly	352.812°
mean_motion	/ day
inclination	19.274°
asc_node	186.989°
arg_peri	172.899°
satellites	0
mean_diameter
sidereal_day	{{Ubl
{{val	6.946	0.05	ul	h}} (single-peaked)
or {{val	13.892	0.05	u	h}} (double-peaked)
albedo
spectral_type	{{Ubl
-type ("double-dip")<ref name	"Pinilla-Alonso2024"/
IR–RR (red)<ref name	"Vilenius2012"/
B–V {{	}}
V–R {{	}}
V–I {{	}}
abs_magnitude	{{Ubl
(2016)<ref name	"Alvarez-Candal2016"/
(2012)<ref name	"Vilenius2012"/
3.69 (JPL)<ref name	"jpldata"/
magnitude	≈ 20 (average)
single_temperature	(perihelion)

|Andrew C. Becker |Andrew W. Puckett |Jeremy M. Kubica | TNO | classical (hot) | distant | Scat-Ext | (single-peaked) |or (double-peaked) | -type ("double-dip") | IR–RR (red) | B–V
| V–R
| V–I
| (2016) | (2012) |3.69 (JPL)

145452 Ritona (provisional designation ****) is a large trans-Neptunian object orbiting the Sun in the Kuiper belt. It was discovered on 10 September 2005 by astronomers Andrew Becker, Andrew Puckett and Jeremy Kubica at Apache Point Observatory in Sunspot, New Mexico. Ritona has a measured diameter of , which is large enough that some astronomers consider it a possible dwarf planet.

Ritona has a dark and reddish surface made of water ice, carbon dioxide ice, carbon monoxide ice, and various organic compounds (tholins). Observations by the James Webb Space Telescope have shown that carbon dioxide ice is more abundant than water ice in Ritona's surface, which suggests that there is a thin layer of carbon dioxide ice covering Ritona's surface. Ritona is not known to have any natural satellites or moons, which means there is currently no way to measure its mass and density.

History

Discovery

Ritona was discovered by astronomers Andrew Becker, Andrew Puckett and Jeremy Kubica on 10 September 2005, during observations for the Sloan Digital Sky Survey. The discovery observations were made using the 2.5-meter telescope at Apache Point Observatory in Sunspot, New Mexico. The discoverers further observed Ritona until November 2005 and found the object in precovery observations from dates as early as June 2001. The discovery of Ritona was announced by the Minor Planet Center on 23 July 2006. Since then, Ritona has been found in even earlier precovery observations dating back to June 1954.

Name and number

The object is named after Ritona, the Celtic goddess of river fords. The naming of this object was announced by the International Astronomical Union's Working Group for Small Body Nomenclature on 21 July 2025. Before Ritona was officially named, it was known by its provisional designation , which indicates the year and half-month of the object's discovery date. Ritona's minor planet catalog number of 145452 was given by the Minor Planet Center on 5 December 2006. The Kuiper belt objects 145451 Rumina and come before and after Ritona's number in the minor planet catalog, respectively.

Orbit

Ritona is a trans-Neptunian object orbiting the Sun at a semi-major axis or average distance of 41.5 astronomical units (AU). It follows a moderately inclined and nearly circular orbit, with a low eccentricity of 0.02 and inclination of 19.3° with respect to the ecliptic. In its 267-year-long orbit, Ritona comes as close as 40.6 AU from the Sun at perihelion and as far as 42.5 AU from the Sun at aphelion. Ritona last passed perihelion in November 1760 and will make its next perihelion passage on 15 April 2029.

Ritona is located in the classical region of the Kuiper belt 39–48 AU from the Sun, and is thus classified as a classical Kuiper belt object (sometimes known as a "cubewano"). The high orbital inclination of Ritona makes it a dynamically "hot" member of the classical Kuiper belt. The hot classical Kuiper belt objects are believed to have been scattered by Neptune's gravitational influence during the Solar System's early history.

Physical characteristics

Size

Ritona has a diameter of 679 km (full range 606 to 734 km when including uncertainties), according to thermal emission measurements by the infrared Herschel Space Observatory. Ritona is large enough that some astronomers consider it a possible dwarf planet.

Surface

In visible light, the surface of Ritona appears dark and reddish in color, with a geometric albedo of about 0.11. Spectroscopic observations by the James Webb Space Telescope (JWST) in 2022 have shown that Ritona's surface is composed of water ice, carbon dioxide () ice, carbon monoxide (CO) ice, and various organic compounds (tholins). Ritona shares this composition with the -type (aka "double-dip") trans-Neptunian objects, which are commonly found on dynamically excited orbits such as those in the hot classical Kuiper belt (where Ritona resides).

Analysis of JWST's spectroscopic observations has shown that Ritona's surface is more abundant in ice than water ice, which suggests that Ritona's surface is covered with a thin (a few micrometres thick) layer of fine, micron-sized ice particles. CO ice is also abundant in Ritona's surface, contrary to theoretical predictions that CO should sublimate and escape from Ritona's surface at its temperature and distance from the Sun. Planetary scientists Michael E. Brown and Wesley C. Fraser have hypothesized that the Sun's ultraviolet light produces CO in Ritona's surface by irradiating and breaking down molecules, and leaves the CO trapped within the surrounding ice. A similar scenario has been hypothesized for , another -rich Kuiper belt object observed by JWST.

Rotation

, observations of Ritona's brightness over time indicate it has a rotation period of either 6.946 or 13.892 hours, depending on whether the object's brightness variability is caused by surface albedo variations or an elongated shape. Studies from 2010 to 2018 have consistently shown that Ritona exhibits very little brightness variation (less than 0.06 magnitudes), which makes it difficult to accurately determine its rotation period. The small brightness variations of Ritona can be explained if it has a spheroidal shape with small albedo variations across its surface.

Notes

References

Info: Wikipedia Source

This article was imported from Wikipedia and is available under the Creative Commons Attribution-ShareAlike 4.0 License. Content has been adapted to SurfDoc format. Original contributors can be found on the article history page.

classical-kuiper-belt-objects discoveries-by-andrew-c.-becker discoveries-by-andrew-w.-puckett discoveries-by-jeremy-martin-kubica astronomical-objects-discovered-in-2005 possible-dwarf-planets named-minor-planets minor-planets-named-after-their-provisional-designation named-tnos

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