List of Solar System objects by size

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This article includes a list of the most massive known objects of the Solar System and partial lists of smaller objects by observed mean radius. These lists can be sorted according to an object's radius and mass and, for the most massive objects, volume, density, and surface gravity, if these values are available.

These lists contain the Sun, the planets, dwarf planets, many of the larger small Solar System bodies (which includes the asteroids), all named natural satellites, and a number of smaller objects of historical or scientific interest, such as comets and near-Earth objects.

Many trans-Neptunian objects (TNOs) have been discovered; in many cases their positions in this list are approximate, as there is frequently a large uncertainty in their estimated diameters due to their distance from Earth. There are uncertainties in the figures for mass and radius, and irregularities in the shape and density, with accuracy often depending on how close the object is to Earth or whether it has been visited by a probe.

Solar System objects more massive than 10²¹ kilograms are known or expected to be approximately spherical. Astronomical bodies relax into rounded shapes (spheroids), achieving hydrostatic equilibrium, when their own gravity is sufficient to overcome the structural strength of their material. It was believed that the cutoff for round objects is somewhere between 100 km and 200 km in radius if they have a large amount of ice in their makeup;<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> however, later studies revealed that icy satellites as large as Iapetus (1,470 kilometers in diameter) are not in hydrostatic equilibrium at this time,<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> and a 2019 assessment suggests that many TNOs in the size range of 400–1,000 kilometers may not even be fully solid bodies, much less gravitationally rounded.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Objects that are ellipsoids due to their own gravity are here generally referred to as being "round", whether or not they are actually in equilibrium today, while objects that are clearly not ellipsoidal are referred to as being "irregular."

Spheroidal bodies typically have some polar flattening due to the centrifugal force from their rotation, and can sometimes even have quite different equatorial diameters (scalene ellipsoids such as Template:Dp). Unlike bodies such as Haumea, the irregular bodies have a significantly non-ellipsoidal profile, often with sharp edges.

There can be difficulty in determining the diameter (within a factor of about 2) for typical objects beyond Saturn Template:Xref. For TNOs there is some confidence in the diameters, but for non-binary TNOs there is no real confidence in the masses/densities. Many TNOs are often just assumed to have Pluto's density of 2.0 g/cm³, but it is just as likely that they have a comet-like density of only 0.5 g/cm³.<ref name="Britt2006">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

For example, if a TNO is incorrectly assumed to have a mass of 3.59Template:E kg based on a radius of 350 km with a density of 2 g/cm³ but is later discovered to have a radius of only 175 km with a density of 0.5 g/cm³, its true mass would be only 1.12Template:E kg.

The sizes and masses of many of the moons of Jupiter and Saturn are fairly well known due to numerous observations and interactions of the Galileo and Cassini orbiters; however, many of the moons with a radius less than ≈100 km, such as Jupiter's Himalia, have far more uncertain masses.<ref name="jplssd">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Further out from Saturn, the sizes and masses of objects are less clear. There has not yet been an orbiter around Uranus or Neptune for long-term study of their moons. For the small outer irregular moons of Uranus, such as Sycorax, which were not discovered by the Voyager 2 flyby, even different NASA web pages, such as the National Space Science Data Center<ref name="nssdc">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> and JPL Solar System Dynamics,<ref name=jplssd/> give somewhat contradictory size and albedo estimates depending on which research paper is being cited.

• Relative masses of the bodies of the Solar System. Objects smaller than Saturn are not visible at this scale.
  Relative masses of the bodies of the Solar System. Objects smaller than Saturn are not visible at this scale.
• Relative masses of the Solar planets. Jupiter at 71% of the total and Saturn at 21% dominate the system.
  Relative masses of the Solar planets. Jupiter at 71% of the total and Saturn at 21% dominate the system.
• Relative masses of the solid bodies of the Solar System. Earth at 48% and Venus at 39% dominate. Bodies less massive than Pluto are not visible at this scale.
  Relative masses of the solid bodies of the Solar System. Earth at 48% and Venus at 39% dominate. Bodies less massive than Pluto are not visible at this scale.
• Relative masses of the rounded moons of the Solar System. Mimas, Enceladus, and Miranda are too small to be visible at this scale.
  Relative masses of the rounded moons of the Solar System. Mimas, Enceladus, and Miranda are too small to be visible at this scale.

The following objects have a nominal mean radius of 400 km or greater. It was once expected that any icy body larger than approximately 200 km in radius was likely to be in hydrostatic equilibrium (HE).<ref name="Brown-dplist">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> However, Template:Dp (r = 470 km) is the smallest body for which detailed measurements are consistent with hydrostatic equilibrium,<ref>Template:Cite journal</ref> whereas Iapetus (r = 735 km) is the largest icy body that has been found to not be in hydrostatic equilibrium.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The known icy moons in this range are all ellipsoidal (except Proteus), but trans-Neptunian objects up to 450–500 km radius may be quite porous.<ref name="Grundy2019">Template:Cite journal</ref>

For simplicity and comparative purposes, the values are manually calculated assuming that the bodies are all spheres. The size of solid bodies does not include an object's atmosphere. For example, Titan looks bigger than Ganymede, but its solid body is smaller. For the giant planets, the "radius" is defined as the distance from the center at which the atmosphere reaches 1 bar of atmospheric pressure.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Because Sedna has no known moons, directly determining its mass (estimated to be from 1.7x10²¹ to 6.1×10²¹ kg<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>) is impossible without sending a probe.

All imaged icy moons with radii greater than 200 km except Proteus are clearly round, although those under 400 km that have had their shapes carefully measured are not in hydrostatic equilibrium.<ref name="Thomas2010"/> The known densities of TNOs in this size range are remarkably low (Template:Val), implying that the objects retain significant internal porosity from their formation and were never gravitationally compressed into fully solid bodies.<ref name="Grundy2019"/> Many intrinsically bright TNOs like Template:Mpl and Template:Mpl do not have directly measured sizes (e.g. via stellar occultation and radiometry of thermal emission), so their sizes are estimated based on an assumed albedo.<ref name="johnston2011"/> In the list below, TNOs with unmeasured sizes are only listed if they have been mentioned in press releases and the scientific literature.

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This list contains a selection of objects estimated to be between 100 and 199 km in radius (200 and 399 km in diameter), being 200 km nicknamed the "potato radius" by astronomers. The largest of these may have a hydrostatic-equilibrium shape, but most are irregular (i.e., potato-shaped). Mass switches from 10²¹ kg to 10¹⁸ kg (Zg). Main-belt asteroids have orbital elements constrained by (2.0 AU < a < 3.2 AU; q > 1.666 AU) according to JPL Solar System Dynamics (JPLSSD).<ref name="mainbelt">{{#invoke:citation/CS1|citation |CitationClass=web }}Template:Dead link</ref> Many TNOs are omitted from this list as their sizes are poorly known.<ref name=johnston2011 />

This list contains a selection of objects 50 and 99 km in radius (100 km to 199 km in average diameter). The listed objects currently include most objects in the asteroid belt and moons of the giant planets in this size range, but many newly discovered objects in the outer Solar System are missing, such as those included in the following reference.<ref name="johnston2011"/> Asteroid spectral types are mostly Tholen, but some might be SMASS.

This list includes few examples since there are about 589 asteroids in the asteroid belt with a measured radius between 20 and 49 km.<ref name=diameter40-100>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Many thousands of objects of this size range have yet to be discovered in the trans-Neptunian region. The number of digits is not an endorsement of significant figures. The table switches from Template:E kg to Template:E kg (Eg). Most mass values of asteroids are assumed.<ref name="Carry2012"/><ref name="Baer2007">Template:Cite journal</ref>

This list contains some examples of Solar System objects between 1 and 19 km in radius. This is a common size for asteroids, comets and irregular moons.

Template:See also This list contains examples of objects below 1 km in radius. That means that irregular bodies can have a longer chord in some directions, hence the mean radius averages out. In the asteroid belt alone there are estimated to be between 1.1 and 1.9 million objects with a radius above 0.5 km,<ref>Template:Cite press release</ref> many of which are in the range 0.5–1.0 km. Countless more have a radius below 0.5 km. Very few objects in this size range have been explored or even imaged. The exceptions are objects that have been visited by a probe, or have passed close enough to Earth to be imaged. Radius is by mean geometric radius. Number of digits not an endorsement of significant figures. Mass scale shifts from × 10¹⁵ to 10⁹ kg, which is equivalent to one billion kg or 10¹² grams (Teragram – Tg). Currently most of the objects of mass between 10⁹ kg to 10¹² kg (less than 1000 teragrams (Tg)) listed here are near-Earth asteroids (NEAs). The Aten asteroid Template:Mp has less mass than the Great Pyramid of Giza, 5.9 × 10⁹ kg. For more about very small objects in the Solar System, see meteoroid, micrometeoroid, cosmic dust, and interplanetary dust cloud. (See also Visited/imaged bodies.)