In my last post, I made the argument that determining whether or not a substellar object is a “planet” or not should be based on size and size alone. In this post, I outline my sliding scale of planet size classification.

Below are the size classes I propose. These size classes were created using an exponential scale, so objects in each size class are larger by a scale of magnitude than the objects in the class below. For the gas giants (first four size classes), mass decreases fivefold at each step down. For terrestrial planets (next four size classes), volume decreases fourfold at each step (which, because more massive objects tend to be more compressed, happens to approximates a fivefold decrease in mass, although it is not rigidly bound to it). For the dwarf planets and demi-planets (four size classes each), volume also decreases fourfold at each step. After that, it decreases ever faster until eventually each step down is a tenfold decrease in geometric radius, which is equal to a thousand-fold decrease in volume. At the “planet” level, the size ranges happen to roughly correspond to actual categorical differences, which are noted in the descriptions below. For smaller objects, the size classes are mostly arbitrary, but differences are noted where applicable. Each size class is indicated both by a letter (“size-B”) and by a name (“Jupiter Class”) that corresponds with an important member of that class.

I have tried to list examples for each size class, including exoplanet and fictional examples where they could be identified. The diameters listed are in most cases my best educated guess. I have indicated official names in

**bold type**, followed by a nickname in “quotes” if the planet has no official name, only a preliminary designation code. A few of these nicknames (Bellerophon, Zarmina, Snow White, Buffy, Drac, Earhart, etc.) were already in use, but in those cases where an object didn’t even have a nickname, I made one up – because every planet deserves a name! There was a method to my madness in choosing nicknames, but my rules were not the same as the IAU’s rules for determining official names. They see Pluto as the Roman god of the underworld and stipulate that all similar objects (“plutinos”) be named after mythological underworld entities as well. To me, though, Pluto is a cartoon dog.

For all objects except the eight major planets, I have indicated their official Minor Planet Center number (Arabic numeral) or satellite number (Roman numeral). However, I outright reject the number the MPC assigned to Pluto (134340). Given Pluto’s historical importance and the decades it spent listed as “one of the nine planets,” I think the MPC should have made an exception to its sequential numbering system, as it did with 20000 Varuna and 50000 Quaoar. Pluto deserves a number in line with its significance as the first object discovered beyond the orbit of Neptune, and I therefore propose using the number zero (0) for it.

Finally, to help illustrate where in the Solar System each object is located, I have used the following letter codes to indicate their orbital zone:

**Dominant planet orbits**

**h-**Objects that share a stable orbit with Mercury (After the Greek name for Mercury, Hermes, to avoid confusion with Mars; note that such objects are hypothetical only, as Mercury has no known satellites or trojans)

**v-**Objects that share a stable orbit with Venus (also hypothetical only)

**e-**Objects that share a stable orbit with Earth (only two are known: e-I Luna, the Earth’s moon, and e- 2010 TK7, the only known Earth trojan. Earth has several co-orbital asteroids, but none of these are stable in their orbits over the long term due to perturbations from the other inner planets)

**m-**Objects that share a stable orbit with Mars (two satellites, plus four known trojans to date and likely many more)

**j-**Objects sharing an orbit with Jupiter (at least 63 satellites, plus hundreds of known Trojans and likely a million all together)

**s-**Objects that share an orbit with Saturn (at least 62 satellites, plus likely undiscovered trojans)

**u-**Objects that share an orbit with Uranus (at least 27 satellites, plus likely undiscovered trojans)

**n-**Objects sharing an orbit with Neptune (at least 13 satellites, plus seven trojans known to date and likely more than Jupiter has in total)

**Other orbits**

**i-**Objects in the inner planetary region (roughly 0-2 AU) that do not share stable orbits with one of the dominant planets, including the near-Earth Amor, Apollo and Aten asteroid groups (for example, i-433 Eros, an Amor asteroid that crosses but does not share the orbit of Mars)

**a-**Objects in the Main Asteroid Belt (roughly 2-5 AU), including not only asteroids (a-1 Ceres, etc.) but also “main belt comets” (a-7968 Elst-Pizarro, etc.)

**o-**Objects in the outer planetary region (roughly 5-30 AU) that do not share stable orbits with one of the dominant planets (for example, o-2060 Chiron, a centaur)

**k-**Trans-Neptunian objects in the Kuiper Belt (roughly 30-50 AU)

**t-**Trans-Neptunian objects beyond the Kuiper Belt (50+ AU), including Scattered Disc objects, etc.

**p-**Objects that have an elongated orbit similar to a periodic comet (defined as a comet with an orbital period less than 200 years, placing them somewhere in the Outer Planetary Region or Scattered Disc at their furthest distance from the Sun)

**c-**Comets and other objects that have very long orbital periods (longer than 200 years, placing them as far away as the Oort Cloud at their furthest distance from the Sun), or are on a hyperbolic trajectory that will make them orbit the Sun only once before being ejected from the Solar System

**d-**Objects that have been destroyed (for example, by collision)

**x-**Objects whose orbital information is unknown (historic comets, lost asteroids, etc.)

Note that codes p-, c-, d- and x- are already used in designating comet types. These same codes, however, are just as applicable to other objects in our Solar System (such as damocloids, which are asteroid-like objects with comet-like orbits), so I have adopted them where appropriate for non-comets as well.

**GIANT PLANETS**

__Size-A: Super-Jupiter Class Giant Planets__

*Picture gallery*

*Size*: >1,250 Earth masses (ME), or roughly >3.93 Jupiter masses

*Description*: “Super-Jupiter” is a common term among astronomers to describe any planet with a mass more than five times that of Jupiter (1,589 times the mass of Earth), but in keeping with a consistent scale, I propose moving the threshold back slightly. This size class represents the most massive a planet may become. Somewhere around 13 times the mass of Jupiter (the exact threshold is a matter of debate), planets become massive enough to experience nuclear fusion of deuterium (“heavy hydrogen”) and are classified as “brown dwarfs,” an intermediate stage between main sequence stars (massive enough to sustain hydrogen-1 fusion) and planets (no fusion). Even though Super-Jupiter Class planets are not nuclear, they are likely to generate a lot of heat and electro-magnetic energy. They are similar to size-B planets in size and composition, but much more dense and thus more massive.

*Solar System Examples*: None currently known, but there’s always a chance that we’ll discover a Super-Jupiter or even a brown dwarf orbiting ridiculously far away from the Sun. That would be awesome.

*Exoplanet examples*: At least 60 Super-Jupiters have been discovered up to 13 MJ, plus more than a dozen others over that size which may be planets or may be brown dwarfs. Examples include

**HD 74156 c**“Dominion” (7.5 MJ),

**Iota Draconis b**“Kairyu” (8.8 MJ),

**Tau Boötis b**“Keymaster” (5.5 MJ), whose yellow-white dwarf star is tidally locked to it, and four Super-Jupiters orbiting HR 8799, a star with about 1.5 times the mass of our Sun:

**HR 8799 b**“Snowhead” (7.0 MJ),

**HR 8799 c**“Woodfall” (10.0 MJ),

**HR 8799 d**“Greatbay” (10.0 MJ) and

**HR 8799 e**“Ikana” (9.0 MJ).

*Fictional example*: Wookieepedia lists

**Yavin Prime**from the original Star Wars as 198,500 km in diameter, which indicates that it is either size-A or size-B. I lean towards the former, as this might explain why the Empire bothered going around it in the first place to get to the Rebel base on the moon Yavin IV, rather than just blowing up the planet and taking out its moons along with it: Yavin Prime was just too immense for even the Death Star’s massive firepower.

__Size-B: Jupiter Class Giant Planets__

*Picture gallery*

*Size*: 250-1,250 Earth masses (ME)

*Description*: In this class, planets have reached the upper limit for size: with additional mass, they will only get denser, not more voluminous. Size-B planets are mostly hydrogen (the simplest and therefore most abundant element), and their great mass compresses their core into metallic hydrogen. In Jupiter Class planets, this generates an extremely strong magnetic field – so strong, in fact, that it will pose a health risk to humans if we ever try to explore the moons of Jupiter.

*Solar System Examples*:

**Jupiter**(318 ME / 142,981 km), of course, and possibly

**Tyche**(300-1,500 ME), a hypothetical planet that some (mostly crazy) astronomers believe lies in the (also hypothetical, but this time not crazy) Oort Cloud approximately 15,000 AU from the Sun (about a quarter of a light year).

*Exoplanet Examples*: More than 170 Jupiter Class exoplanets have been discovered to date, including

**Gliese 876 b**“Cthulhu” (601 ME),

**HD 74156 b**“Mayor” (496 ME) and

**Gamma Cephei Ab**“Kong” (at least 509 ME).

*Fictional Example*:

**Tana**was the gas giant that the moon of Endor revolved around in

*Star Wars: Return of the Jedi*. Based on the diameter listed for it on Wookieepedia (148,000 km), it was most likely size-B, although size-A is also possible.

__Size-C: Saturn Class Giant Planets__

*Picture gallery*

*Size*: 50-250 ME

*Description*: Like Jupiter Class planets, Saturn Class ones are mostly hydrogen and are massive enough to contain metallic hydrogen cores. However, they are less dense and their magnetic fields are weaker. Also, because of their lower density, they have lower “surface” gravity than larger gas giants. (Saturn’s surface gravity is only 1.07 times that of Earth, so a floating station like the “Cloud City” from Star Wars could be feasible in at least one regard.)

*Solar System Example*:

**Saturn**(95 ME / 120,536 km) possesses the most extensive and complex satellite system of any planet we know, with several features (extensive rings, ring moonlets, co-orbital satellites, trojan satellites, etc.) that we have seen nowhere else. It may be that Saturn’s size and mass factor into this, creating a gravitational environment where such oddities can flourish. Or it may just be coincidence.

*Exoplanet Examples*: More than 120 Saturn Class planets have been discovered so far, including

**51 Pegasi b**“Bellerophon” (150 ME),

**Gliese 876 c**“Hastur” (178 ME), and sister planets

**OGLE-2006-BLG-109L b**“Aang” (231 ME) and

**OGLE-2006-BLG-109L c**“Korra” (86 ME).

*Fictional Examples*: In

*Star Wars: The Empire Strikes Back*, a habitable zone in the upper atmosphere of

**Bespin**(118,000 km) was the site of the floating Cloud City. In Avatar,

**Polyphemus**(108,482 km) was the planet around which the moon Pandora revolved.

__Size-D: Neptune Class Giant Planets__

*Picture gallery*

*Size*: 10-50 ME

*Description*: Like other gas giants, Neptune Class planets are massive enough to retain light gasses like hydrogen in their atmosphere. However, unlike Saturn Class and larger planets, Neptune Class planets are not massive enough to condense hydrogen into a metallic state at their cores. Instead, they have cores that are mainly ices (water, methane, ammonia) mixed with some rock and gas. For this reason, they are sometimes called “ice giants” instead of “gas giants.” Because they are mostly made of light gasses, these planets are not very dense and their “surface” gravity is roughly comparable to Saturn or Earth Class planets. (Uranus and Neptune have 0.89 and 1.12 times Earth’s gravity, respectively.)

*Solar System Examples*:

**Neptune**(14.5 ME / 49,500 km),

**Uranus**(14.5 ME / 51,118 km).

*Exoplanet Examples*: At least 20 Neptune Class planets have been discovered so far, including

**Gliese 581 b**“Zibanu” (15.6 ME) and

**Gliese 876 e**“Ithaqua” (14.6 ME), which orbit red dwarf stars, and

**Kepler 11 c**“Kal-El” (13.5 ME) and

**Kepler 11 g**“Kara” (mass unknown, but radius about equal to Naptune), which orbit a star much like our Sun.

*Fictional Examples*: I couldn’t find any love for Neptune Class planets in fiction. Boo.

**TERRESTRIAL PLANETS**

__Size-E: Super-Earth Class Terrestrial Planets__

*Picture gallery*

*Size*: >16,000 km and <10 ME

*Description*: Super-Earths are approximately two to ten times the mass of Earth, the largest a planet can get without retaining a large amount of light gasses in its atmosphere and becoming a gas giant. (Since we have very little data on planets of this size, the boundary between Super-Earth and Neptune Class planets is largely theoretical now. For the sake of convenience, we will assume it happens at around 10 times the mass of Earth, but in time we may find large Super-Earths that behave more like Neptunes or small Neptune Class planets that behave more like Super-Earths, in which case we will want to refine our classification criteria.) Super-Earth Class planets may be Earth-like in many ways, but they have extremes like high surface gravity and dense atmospheres. Their high gravity may also make them more geologically active, depending on their composition.

*Solar System Examples*: None known.

*Exoplanet Examples*: More than a dozen Super-Earth Class exoplanets have been discovered to date. These include four of the planets around red dwarf Gliese 581:

**Gliese 581 c**“Ymir” (5.6 ME), Gliese

**581 d**“Zoso” (5.6 ME),

**Gliese 581 g**“Zarmina” (3.1 ME) and

**Gliese 581 f**“Bangalla” (7.0 ME). The last two are speculative right now, but if future data confirm the existence of Zarmina, it will be the first exoplanet discovered in its star’s habitable zone. Other Super-Earths include

**Gliese 876 d**“Tsathoggua” (7.7 ME); pulsar-orbiting

**PSR B1257+12 c**“Elphaba” (4.3 ME) and

**PSR B1257+12 d**“Glinda” (3.9 ME), two of the first exoplanets ever discovered; and four planets around Sun-like star Kepler 11:

**Kepler 11 b**“Lara” (4.3 ME),

**Kepler 11 d**“Jor-El” (6.1 ME),

**Kepler 11 e**“Zor-El” (8.4 ME) and

**Kepler 11 f**“Alura” (2.3 ME).

*Fictional Examples*: In DC comics, it seems likely that Superman’s home planet

**Krypton**is Super-Earth Class, although its exact size is not specified. Other Super-Earths include the ocean-planet

**Kamino**(19,270 km), where the clones were bioengineered in

*Star Wars Episode II*;

**Londinium**(18,000 km), the central planet of the Alliance in the Firefly universe; and

**Qo’noS**(18,200 km), the Klingon home world from the Star Trek universe.

__Size-F: Earth Class Terrestrial Planets__

*Picture gallery*

*Size*: 10,000-16,000 km

*Description*: Earth Class planets are between 50% and 200% the volume of our own planet, and they are pretty much what you’d expect: surface gravity not too far from Earth’s, an atmosphere probably about as thick as ours (although probably not composed of the same gasses), and a differentiated interior (for example, an iron-nickel core surrounded by a rocky mantle). Earth Class planets inside the habitable zones of their star systems are the prime candidates for future extrasolar colonization. As soon as we find some, that is.

*Solar System Examples*:

**Earth**(12,742 km) and

**Venus**(12,100 km).

*Exoplanet Examples*:

**Gliese 581 e**“Toro” (1.9 ME) and

**Alpha Centauri Bb**“Sheol” (1.0 ME) appear to orbit too close to their stars to support life, but countless Earth-sized exoplanets in their stars' habitable zones await our discovery.

*Fictional Examples*: As can be imagined, the vast majority of fictional planets fall into this category. From Star Wars, we get

**Kashyyyk**(12,765 km), home planet of the Wookiees;

**Alderaan**(12,500 km), Princess Leia’s home planet before it was destroyed by the Death Star;

**Coruscant**(12,240 km), seat of the galactic government;

**Naboo**(12,120 km), home of Padmé Amidala and Jar-Jar Binks;

**Geonosis**(11,370 km), where the droid army was built and plans for the Death Star created;

**Tatooine**(10,465), which you either know or there’s no sense explaining it; and

**Yavin IV**(10,200 km), the moon where the Rebel base was located in the first film. This class also includes

**Pandora**(11,447 km), the satellite planet where James Cameron’s

*Avatar*was set;

**LV-426**(12,201 km), the setting of

*Alien*and

*Aliens*;

**Arrakis**(12,256 km), the central planet of Frank Herbert’s Dune series;

**Persephone**(14,613),

**Miranda**(11,023 km) and most of the other inhabited planets from the Firefly universe; and

**Oerth**(13,428 km), one of the main settings for the Dungeons & Dragons game (a big rip-off of Middle Earth, which I couldn’t find a reference for, so this will have to do).

**Darwin IV**(from Wayne Douglas Barlowe’s book

*Expedition*, later adapted into the

*Alien Planet*television special),

**Mongo**(from Flash Gordon),

**Pern**(from the Anne McCaffrey series of books),

**Trantor**(from Isaac Asmiov’s Foundation series),

**Ceti Alpha V**(the planet where Khan Noonien Singh and his followers were marooned at the start of

*Star Trek II: The Wrath of Khan*),

**Romulus**and

**Remus**(home worlds of the Romulans in Star Trek),

**Vulcan**(Spock’s home world in the Star Trek universe), and

**Caprica**and the rest of the Twelve Colonies (from Battlestar Galactica) are also almost certainly Earth Class planets, even though their exact dimensions are never specified as far as I can tell.

__Size-G: Mars Class Terrestrial Planets__

*Picture gallery*

*Size*: 6,000-10,000 km

*Description*: Mars Class planets are massive enough to dominate their orbits all the way out to at least 50 AU, which is the far edge of the Kuiper Belt in our Solar System. They have lower gravity and thinner atmospheres, but are still reasonable candidates for human colonization. (Speaking of which, we need to start terraforming Mars immediately.)

*Solar System Examples*:

**Mars**itself is actually a pretty small example of this size class at only 6,787 km in diameter.

**Theia**is the name usually given to the hypothetical Mars-sized planet that many scientists believe collided with Earth approximately 4.5 billion years ago, forming our moon, Luna, in the process.

*Fictional Examples*: According to Wookieepedia,

**Mandalore**(9,200 km), home of the fan-boy favorite Mandalorians;

**Dagobah**(8.900 km), where Luke meets Yoda; and the ice planet

**Hoth**(7,200 km) from the Star Wars universe are all Mars Class planets. Terry Pratchet’s

**Discworld**is flat, not round, but if it were turned into a sphere it too would be a Mars Class planet, about 8,000 km in diameter.

*Picture gallery*

*Size*: 4,000-6,000 km

*Description*: Mercury Class planets are massive enough to dominate their orbits to at least 10 AU, which is about the orbit of Saturn in our Solar System. They are likely to have differentiated interiors, and the more massive likely have thin atmospheres as well (although Mercury’s has mostly been stripped off by the force of the solar wind). Planets of this size are probably the smallest possible candidates for large-scale permanent human colonization, although the low gravity and thin atmosphere will pose serious challenges.

*Solar System Examples*: j-III

**Ganymede**(5,262 km), s-IV

**Titan**(5,150 km),

**Mercury**(4,878 km), j-IV

**Callisto**(4,821 km).

*Exoplanet Example*:

**PSR B1257+12 b**“Pastoria” orbits a pulsar and is believed to be about 2% of the mass of Earth, which would probably make it a Mercury Class planet.

*Fictional Examples*: From Star Wars, we get the moon of

**Endor**(4,900 km), home of the Ewoks from

*Star Wars: Return of the Jedi*, and

**Mustafar**(4,200 km), the volcano planet from

*Episode III*. From Firefly, this class includes resort planet

**Pelorum**(5,700 km).

**Mogo**(5,824 km), the sentient planet and member of the Green Lantern Corps from DC comics, is also Mercury Class.

**DWARF PLANETS**

__Size-I: Luna Class Dwarf Planets__

*Picture gallery*

*Size*: 2,500-4,000 km

*Description*: Luna Class planets are massive enough to potentially dominate a near-star orbit, but not much further than 1 AU. They likely have differentiated interiors, but their atmospheres are tenuous at best. The diameter of these planets is less than the width of the United States (roughly 4,200 km from New York to San Francisco).

*Solar System Examples*: j-I

**Io**(3,643 km), e-I

**Luna**(3,473 km), j-II

**Europa**(3,122 km), n-I

**Triton**(2,707 km).

*Fictional Examples*: From the Firefly universe, we get neo-Amish planet

**Triumph**(3,640 km) and

**Colchester**(3,145 km), an inhabited moon of Londinium.

*Picture gallery*

*Size*: 1,600-2,500 km

*Description*: Pluto Class planets likely have differentiated interiors, but permanent atmospheres are missing or negligible. They could dominate their orbit only if it was very close to the Sun. The diameter of these planets is roughly equal to the size of Alaska (1,300 km wide x 2,400 km long).

*Solar System Examples*: k-0

**Pluto**(2,370 km), t-136199

**Eris**(2,326 km).

*Fictional Examples*: According to famous comic book artist John Byrne, DC Comics'

**Apokolips**and

**New Genesis**are planets "much smaller than our Moon."

*Description*: Titania Class planets likely have differentiated interiors, but no permanent atmosphere. It is doubtful they could dominate any orbit, although it may be possible for a super-close, “star-skimming” orbit. The diameter of these planets is roughly equal to the size of Texas (1,060 km wide x 1,270 km long).

*Solar System Examples*: u-III

**Titania**(1,578 km), s-V

**Rhea**(1,528 km), u-IV

**Oberon**(1,523 km), s-VIII

**Iapetus**(1,436 km), k-136472

**Makemake**(1,426 km), t-225088

**2007OR10**“Snow White” (1,290 km), k-136108

**Haumea**(1,252 km), k-0 Pluto I

**Charon**(1,207 km), u-II

**Umbriel**(1,169 km), u-I

**Ariel**(1,156 km), s-IV

**Dione**(1,120 km), k-50000

**Quaoar**(1,092 km), s-III

**Tethys**(1,056 km), t-90377

**Sedna**(1,041 km), etc.

*Exoplanet Example*:

**PSR B1257+12 d**“Boq” is unconfirmed, but may be the first dwarf exoplanet every discovered. It appears to be very small, less than 20% the mass of Pluto, or about 4/10,000 the mass of Earth.

__Size-L: Ceres Class Dwarf Planets__

*Picture gallery*

*Size*: 600-1,000 km

*Description*: Ceres Class planets are massive enough to achieve hydrostatic equilibrium, whether they are composed of predominantly rigid, rocky materials or more fluid, icy ones. They are likely to have at least partially differentiated interiors.

*Solar System Examples*: k-90482

**Orcus**(983 km), k-307261

**2002MS4**“Conan” (960 km), a-1

**Ceres**(952 km), k-202421

**2005UQ513**“Zelda” (924 km), k-120347

**Salacia**(921 km), k-20000

**Varuna**(762 km), k-208996

**2003AZ84**“Marmaduke” (747 km), k-55565

**2002AW197**“Organa” (728 km), k-55637

**2002UX25**“Ripley” (704 km), k-90568

**2004GV9**“Optimus” (703 km), k-

**2005RN43**“Gandalf” (697 km), k-28978

**Ixion**(674 km), k-174567

**Varda**(692 km), t-

**2006QH181**“Serling” (628 km), k-

**2007JJ43**“Gojira” (614 km), t-229762

**2007UK126**“Logan” (612 km), k-19521

**Chaos**(612 km), etc.

*Fictional Examples*: Several of the terraformed moons of the Firefly universe fall into this size category, including the smallest,

**Ita**(965 km). In the Dune universe, this was the size of one of the two surviving moons of Arrakis,

**Krelln**(976 km). Although artificial, the second

**Death Star**(900 km) from

*Star Wars: Return of the Jedi*would also fit into this size class. (Note that this second battle station absolutely dwarfed the Empire’s first attempt – pun intended – which was equal to a size-O planetoid.)

**DEMI-PLANETS**

__Size-M: Pallas Class Demi-Planets__

*Picture gallery*

*Size*: 400-600 km

*Description*: Pallas Class demi-planets are massive enough that most will be in hydrostatic equilibrium (icy ones almost certainly will, while rocky ones may be under the right circumstances). They will also usually have at least partially differentiated interiors.

*Solar System Examples*: k-230965

**2004XA192**“Knieval” (599 km), t-

**2010KZ39**“Tam” (599 km), t-84522

**2002TC302**“Tiberius” (591 km), k-

**2010RF43**“Ackbar” (585 km), t-15874

**1996TL66**“Pevensie” (575 km), t-42301

**2001UR163**“Sulu” (571 km), k-

**2003UZ413**“Taz” (571 km), k-

**2002XV93**“Gromit” (564 km), t-

**2008ST291**“Yoda” (558 km), k-

**2010RE64**“Deering” (558 km), k-

**2010FX86**“Harryhausen” (558 km), t-145451

**2005RM43**“Kenobi” (545 km), k-

**2004NT33**“Bowie” (545 km), t-

**2004XR190**“Buffy” (545 km), a-2

**Pallas**(544 km), k-84922

**2003VS2**“Scooby” (537 km), k-120348

**2004TY364**“Maximus” (532 km), a-4

**Vesta**(529 km), k-144897

**2004UX10**“Balto” (529 km), k-

**2004PR107**“Padmé” (529 km), k-

**2010VK201**“Ting” (519 km), k-

**2008AP129**“Axel” (507 km), t-

**2003QX113**“Aragorn” (507 km), k-

**2007JH43**“Dino” (507 km), k-

**2001QF298**“Snoopy” (505 km), k-175113

**2004PF115**“Toto” (505 km), s-II

**Enceladus**(494 km), k-

**2001KA77**“Han” (494 km), t-

**2010VZ98**“Fett” (472 km), t-

**2010EK139**“Starbuck” (470 km), u-V

**Miranda**(468 km), k-38628

**Huya**(466 km), t-26375

**1999DE9**“Uhura” (461 km), k-35671

**1998SN165**“Stitch” (460 km), t-

**2008QY40**“Matrix” (450 km), k-120132

**2003FY128**“Sparrow” (440 km), k-

**2003QX111**“T'challa” (434 km), a-10

**Hygiea**(431 km), t-82075

**2000YW134**“Worf” (431 km), k-

**1999CD158**“Elrond” (420 km), n-VIII

**Proteus**(416 km), t-

**2005QU182**“Duke” (415 km), t-26181

**1996GQ21**“Qui-Gon” (401 km), k-119979

**2002WC19**“Sarek” (400 km), etc.

*Fictional Example*: In the Dune universe, this was the size of the smaller moon of Arrakis,

**Arvon**(402 km).

__Size-N: Interamnia Class Demi-Planets__

*Picture gallery*

*Size*: 250-400 km

*Description*: Interamnia Class demi-planets are unlikely to have achieved hydrostatic equilibrium, with most being “potato shaped” (approximately spherical) objects. However, some icy planetoids of this size may be spherical. At this size, we start to see a logarithmic increase in the number of objects.

*Solar System Examples*: k-

**2003QW90**“Tron” (396 km), s-I

**Mimas**(392 km), k-55638

**2002VE95**“Courage” (383 km), t-145480

**2005TB190**“Miagi” (373 km), t-

**2004PG115**“Windu” (359 km), k-174567 Varda I

**Ilmarë**(353 km), n-II

**Nereid**(340 km), k-90482 Orcus I

**Vanth**(330 km), k-47932

**2000GN171**“Droopy” (321 km), a-704

**Interamnia**(317 km), x-

**1995SN55**“Glenstorm” (310 km), k-136108 Haumea I

**Hi'iaka**(310 km), t-79978

**1999CC158**“Chekov” (304 km), a-52

**Europa Minor**(301 km), k-79360

**1997CS29 I**“Jane” (292 km), a-511

**Davida**(289 km), a-87

**Sylvia**(286 km), k-55636

**2002TX300**“Magnum” (286 km), k-120178

**2003OP32**“Opie” (230 km), t-48639

**1995TL8**“Zaphod” (352 km), k-

**2002CY248**“Swayze” (383 km), k-15789

**1993SC**“Dogbert” (363 km), t-40314

**1999KR16**“Mugatu” (304 km), t-26308

**1998SM165**“Saavik” (287 km), k-47171

**1999TC36**“Ren” (286 km), t-65489

**Ceto**(284 km), k-38083

**Rhadamanthus**(274 km), a-65

**Cybele**(273 km), s-VII

**Hyperion**(270 km), k-47171

**1999TC36 I**“Stimpy” (265 km), k-79983

**1999DF9**“Bueller” (265 km), k-148780

**Altjira**(264 km), a-107

**Camilla**(259 km), o-10199

**Chariklo**(259 km), a-31

**Euphrosyne**(256 km), a-15

**Eunomia**(255 km), t-148209

**2000CR105**“Jimi” (253 km), k-145453

**2005RR43**“McFly” (252 km), etc.

__Size-O: Juno Class Demi-Planets__

*Picture gallery*

*Size*: 160-250 km

*Description*: Juno Class demi-planets are very unlikely to have achieved hydrostatic equilibrium, although it is still theoretically possible for icy bodies of this size.

*Solar System Examples*: k-79360

**Sila**(243 km), t-119878

**2002CY224**“Sawyer” (242 km), t-82075

**200YW134 I**“Yar” (237 km), a-3

**Juno**(234 km), o-2060

**Chiron**(233 km), a-88

**Thisbe**(232 km), t-

**2003LA7**“Seldon” (231 km), k-79360 Sila I

**Nunam**(230 km), k-

**2002KW14**“Montoya” (230 km), t-

**2004VN112**“MacGyver” (230 km), a-324

**Bamberga**(228 km), a-451

**Patientia**(225 km), a-19

**Fortuna**(225 km), a-532

**Herculina**(222 km), a-48

**Doris**(222 km), a-375

**Ursula**(216 km), a-45

**Eugenia**(214 km), s-IX

**Phoebe**(213 km), a-29

**Amphitrite**(212 km), k-53311

**Deucalion**(211 km), k-33001

**1997CU29**“Lando” (211 km), a-423

**Diotima**(209 km), t-181902

**1999RD215**“Eastwood” (209 km), a-13

**Egeria**(208 km), a-94

**Aurora**(205 km), k-55637

**2002UX25 I**“Newt” (205 km), j-624

**Hektor**(203 km), t-119068

**2001KC77**“Crusher” (201 km), a-7

**Iris**(200 km), t-19308

**1996TO66**“Lebowski” (200 km), a-24

**Themis**(198 km), a-702

**Alauda**(195 km), n-VII

**Larissa**(194 km), o-54598

**Bienor**(193 km), t-42355

**Typhon**(193 km), t-85633

**1998KR65**“Spaceghost” (192 km), a-121

**Hermione**(190 km), k-120347 Salacia I

**Actaea**(190 km), a-372

**Palma**(189 km), a-128

**Nemesis**(188 km), a-16

**Psyche**(186 km), a-6

**Hebe**(185 km), o-5145

**Pholus**(185 km), a-154

**Bertha**(185 km), a-76

**Freia**(184 km), k-88611

**Teharonhiawako**(184 km), k-66652

**Borasisi**(183 km), k-59358

**1999CL158**“Anakin” (183 km), a-130

**Elektra**(182 km), k-119070

**2001KP77**“Legolas” (182 km), n-

**2006RJ103**“Namor” (180 km), k-119951

**2002KX14**“Chewbacca” (180 km), s-X

**Janus**(179 km), a-259

**Aletheia**(179 km), n-VI

**Galatea**(176 km), k-19255

**1994VK8**“Spartacus” (175 km), a-120

**Lachesis**(174 km), k-24835

**1995SM55**“McGarrett” (174 km), a-41

**Daphne**(174 km), a-9

**Metis**(174 km), a-747

**Winchester**(172 km), a-153

**Hilda**(171 km), a-790

**Pretoria**(170 km), j-VI

**Himalia**(170 km), k-136108 Haumea II

**Namaka**(170 km), a-96

**Aegle**(170 km), a-241

**Germania**(169 km), a-194

**Prokne**(168 km), a-566

**Stereoskopia**(168 km), j-V

**Amalthea**(167 km), j-911

**Agamemnon**(167 km), a-22

**Kalliope**(166 km), a-54

**Alexandria**(166 km), a-386

**Siegena**(165 km), a-59

**Elpis**(165 km), j-1437

**Diomedes**(164 km), a-444

**Gyptis**(163 km), u-XV

**Puck**(162 km), a-409

**Aspasia**(161 km), t-48639

**1995TL8 I**“Trillian” (161 km), k-15760

**1992QB1**“Cubewan” (160 km), a-209

**Dido**(160 km), n-

**2007VL305**“Dorma” (160 km), k-15875

**1996TP66**“Peabody” (160 km), etc.

*Fictional Example*: The

**Death Star**(160 km) from the original

*Star Wars*film: “That’s no moon; it’s a space station.”

__Size-P: Astraea Class Demi-Planets__

*Picture gallery*

*Size*: 100-160 km

*Description*: Bodies of this size will not be able to achieve hydrostatic equilibrium, although many will still be roughly spherical.

*Solar System Examples*: a-334

**Chicago**(159 km), a-804

**Hispania**(158 km), a-185

**Eunike**(158 km), a-139

**Juewa**(157 km), a-354

**Eleonora**(155 km), a-85

**Io Minor**(155 km), a-165

**Loreley**(155 km), a-173

**Ino**(154 km), a-11

**Parthenope**(153 km), k-137295

**1999RB216**“T’Pau” (153 km), a-14

**Irene**(152 km), a-89

**Julia**(152 km

**),**a-536

**Merapi**(151 km), a

**-**776

**Berbericia**(151 km), a-145

**Adeona**(151 km), a-150

**Nuwa**(151 km), t-145474

**2005SA278**“Sokko” (151 km), t-136199 Eris I

**Dysnomia**(150 km), n-V

**Despina**(150 km), u-XVII

**Sycorax**(150 km), a-49

**Pales**(150 km), a-39

**Laetitia**(150 km), a-117

**Lomia**(149 km), a-238

**Hypatia**(149 km), a-168

**Sibylla**(148 km), a-283

**Emma**(148 km), k-118378

**1999HT11**“Arwen” (146 km), a-20

**Massalia**(145 km), a-18

**Melpomene**(141 km), n-

**2001QR322**“Thakorr” (140 km), k-20161

**1996TR66**“Tuvok” (139 km), k-47171

**1999TC36 II**“Mr. Horse” (139 km), t-69988

**1998WA31**“Montgomery” (139 km), k-

**2003UZ117**“Kalakaua” (138 km), u-XII

**Portia**(135 km), k-

**1998WW31**“Rocky” (133 km), t-65489 Ceto I

**Phorcys**(132 km), a-8

**Flora**(128 km), a-654

**Zelinda**(127 km), a-426

**Hippo**(127 km), a-47

**Aglaja**(127 km), a-279

**Thule**(127 km), k-119979

**2002WC19 I**“Grayson” (127 km), a-92

**Undina**(126 km), j-1173

**Anchises**(126 km), j-1143

**Odysseus**(126 km), a-469

**Argentina**(126 km), a-159

**Aemilia**(125 km), a-405

**Thia**(125 km), a-602

**Marianna**(125 km), a-46

**Hestia**(124 km), a-216

**Kleopatra**(124 km), a-104

**Klymene**(124 km), a-410

**Chloris**(124 km), a-134

**Sophrosyne**(123 km), a-328

**Gudrun**(123 km), j-1867

**Deiphobus**(123 km), a-68

**Leto**(122 km), a-70

**Panopaea**(122 km), a-127

**Johanna**(122 km), a-276

**Adelheid**(122 km), k-88611 Teharonhiawako I

**Sawiskera**(122 km), a-176

**Iduna**(121 km), a-156

**Xanthippe**(121 km), a-28

**Bellona**(121 km), k-15809

**1994JS**“Gimli” (121 km), a-86

**Semele**(120 km), a-78

**Diana**(120 km), a-381

**Myrrha**(120 km), a-225

**Henrietta**(120 km), a-618

**Elfriede**(120 km), t-73840

**2002PN34**“Shrute” (120 km), a-105

**Artemis**(119 km), a-81

**Terpsichore**(119 km), a-5

**Astraea**(119 km), a-74

**Galatea**(118 km), a-350

**Ornamenta**(118 km), a-772

**Tanete**(118 km), a-476

**Hedwig**(117 km), a-1093

**Freda**(117 km), a-171

**Ophelia**(117 km), a-909

**Ulla**(116 km), j-3317

**Paris**(116 km), a-203

**Pompeja**(116 km), j-3063

**Makhaon**(116 km), a-38

**Leda**(116 km), a-360

**Carlova**(116 km), a-521

**Brixia**(116 km), a-490

**Veritas**(116 km), a-466

**Tisiphone**(116 km), t-136120

**2003LG7**“Trinity” (116 km), a-53

**Kalypso**(115 km), j-2241

**Alcathous**(115 km), a-388

**Charybdis**(114 km), a-34

**Circe**(114 km), s-XI

**Epimetheus**(113 km), a-596

**Scheila**(113 km), a-56

**Melete**(113 km), a-129

**Antigone**(113 km), a-12

**Victoria**(113 km), a-57

**Mnemosyne**(113 km), a-545

**Messalina**(111 km), j-2797

**Teucer**(111 km), j-2920

**Automedon**(111 km), k-

**1998WW31 I**“Bullwinkle” (111 km), a-91

**Aegina**(110 km), a-140

**Siwa**(110 km), a-814

**Tauris**(110 km), a-595

**Polyxena**(109 km), a-230

**Athamantis**(109 km), j-659

**Nestor**(109 km), a-37

**Fides**(108 km), a-23

**Thalia**(108 km), a-739

**Mandeville**(108 km), a-40

**Harmonia**(107 km), a-181

**Eucharis**(107 km), a-346

**Hermentaria**(107 km), a-357

**Ninina**(106 km), a-514

**Armida**(106 km), a-506

**Marion**(106 km), a-365

**Corduba**(106 km), a-36

**Atalante**(106 km), a-713

**Luscinia**(106 km), a-1269

**Rollandia**(105 km), a-164

**Eva**(105 km), a-98

**Ianthe**(105 km), a-240

**Vanadis**(104 km), a-221

**Eos**(104 km), a-788

**Hohensteina**(104 km), a-791

**Ani**(104 km), k-29981

**1999TD10**“Ditka” (104 km), j-1208

**Troilus**(103 km), a-192

**Nausikaa**(103 km), a-63

**Ausonia**(103 km), a-35

**Leukothea**(103 km), a-570

**Kythera**(103 km), a-233

**Asterope**(103 km), j-4063

**Euforbo**(102 km), j-1583

**Antilochus**(102 km), a-1390

**Abastumani**(102 km), a-522

**Helga**(101 km), a-175

**Andromache**(101 km), a-191

**Kolga**(101 km), a-663

**Gerlinde**(101 km), a-626

**Notburga**(101 km), a-387

**Aquitania**(101 km), a-42

**Isis**(100 km), a-30

**Urania**(100 km), a-50

**Virginia**(100 km), a-114

**Kassandra**(100 km), n-

**2008LC18**“Orin” (100 km), n-

**2004UP10**“Tyrak” (100 km), n-

**2005TO74**“Byrrah” (100 km), etc.

**PLANETOIDS**

__Size-Q: Thetis Class Planetoids__

*Picture gallery*

*Size*: 50-100 km

*Description*: There are estimated to be roughly 400 planetoids of this size in the Main Asteroid Belt alone.

*Solar System Examples*: a-1021

**Flammario**(99 km), a-162

**Laurentia**(99 km), a-401

**Ottilia**(99 km), j-XIV

**Thebe**(99 km), a-21

**Lutetia**(96 km),u-XI

**Juliet**(94 km), k-0 Pluto II

**Nix**(92 km), a-103

**Hera**(91 km), a-17

**Thetis**(90 km), u-XIV

**Belinda**(90 km), a-90

**Antiope**(88 km), j-VII

**Elara**(86 km), s-XVI

**Prometheus**(86 km), a-90

**Antiope I**“Amphion” (84 km), o-60558

**Echeclus**(84 km), n-IV

**Thalassa**(82 km), a-83

**Beatrix**(81 km), s-XVII

**Pandora**(81 km), u-IX

**Cressida**(80 km), n-

**2005TN53**“Orka” (80 km), t-42355 Typhon I

**Echidna**(78 km), k-58534

**Logos**(77 km), o-55576

**Amycus**(76 km), o-8405

**Asbolus**(74 km), k-50000 Quaoar I

**Weywot**(74 km), u-XVI

**Caliban**(72 km), u-XIII

**Rosalind**(72 km), k-86047

**1999OY3**“Higgins” (72 km), o-10370

**Hylonome**(70 km), k-130391

**2000JG81**“T’Pring” (67 km), n-III

**Naiad**(66 km), k-58534 Logos I

**Zoe**(66 km), a-44

**Nysa**(65 km), u-X

**Desdemona**(64 km), n-IX

**Halimede**(62 km), o-52975

**Cyllarus**(62 km), a-60

**Echo**(60 km), j-VIII

**Pasiphaë**(60 km), n-XIII

**Neso**(60 km), o-7066

**Nessus**(60 km), c-C/1995O1

**Comet Hale-Bopp**(60 km), p-

**2008KV42**“Drac” (59 km), k-0 o-52872

**Okyrhoe**(52 km), u-VIII

**Bianca**(51 km), u-XVIII

**Prospero**(50 km), o-83982

**Crantor**(50 km), etc.

__Size-R: Eros Class Planetoids__

*Picture gallery*

*Size*: 10-50 km

*Description*: There are roughly 9,500 planetoids of this size in the Main Asteroid Belt alone. An object this size would cause catastrophic mass extinction if it struck the Earth. This size class includes the asteroid that created the Chicxulub Crater in Mexico and killed off the dinosaurs 65 million years ago, as well as the largest near-Earth asteroids known today (Ganymed and Eros).

*Solar System Examples*: a-123

**Brunhild**(48 km), j-4348

**Poulydamas**(48 km), u-XIX

**Setebos**(48 km), a-2597

**Arthur**(47 km), a-2598

**Merlin**(47 km), j-XI

**Carme**(46 km), a-170

**Maria**(44 km), n-XI

**Sao**(44 km), a-7320

**Potter**(43 km), j-XVI

**Metis**(43 km), u-VII

**Ophelia**(43 km), n-XII

**Laomedeia**(42 km), s-XXIX

**Siarnaq**(40 km), n-X

**Psamathe**(40 km), u-VI

**Cordelia**(40 km), j-IX

**Sinope**(38 km), o-944

**Hidalgo**(38 km), k-0 Pluto III

**Hydra**(38 km), o-49036

**Pelion**(37 km), o-29P

**Schwassmann-Wachmann 1**(37 km), j-X

**Lysithea**(36 km), a-158

**Koronis**(35 km), s-XII

**Helene**(33 km), i-1036

**Ganymed**(32 km), a-1815

**Beethoven**(32 km), s-XXVI

**Albiorix**(32 km), u-XX

**Stephano**(32 km), a-243

**Ida**(31 km), a-4025

**Ridley**(30 km), s-XV

**Atlas**(30 km), u-XXV

**Perdita**(30 km), o-31824

**Elatus**(30 km), a-797

**Montana**(29 km), a-22 Kalliope I

**Linus**(28 km), j-XII

**Ananke**(28 km), s-XVIII

**Pan**(28 km), a-1373

**Cincinnati**(27 km), s-XIII

**Telesto**(25 km), u-XXVI

**Mab**(25 km), a-2779

**Mary**(24 km), k-0 Pluto IV

**Kerberos**(23 km), m-I

**Phobos**(22 km), s-XX

**Paaliaq**(22 km), u-XXII

**Francisco**(22 km), a-2309

**Mr. Spock**(21 km), s-XIV

**Calypso**(21 km), a-149

**Medusa**(20 km), a-434

**Hungaria**(20 km), u-XXIII

**Margaret**(20 km), u-XXIV

**Ferdinand**(20 km), i-9007

**James Bond**(19 km), i-19304

**Cheshirecat**(18 km), a-2488

**Bryan**(18 km), a-87 Sylvia I

**Romulus**(18 km), s-XIX

**Ymir**(18 km), u-XXVII

**Cupid**(18 km), u-XXI

**Trinculo**(18 km), k-0 Pluto V

**Styx**(18 km), i-433

**Eros**(17 km), j-XV

**Adrastea**(16 km), j-XIII

**Leda**(16 km), s-XXIV

**Kiviuq**(16 km), s-XXI

**Tarvos**(15 km), p-65407

**2002RP120**“Nosferatu” (15 km), a-45 Eugenia I

**Petit-Prince**(13 km), m-II

**Deimos**(13 km), a-5715

**Kramer**(12 km), a-121

**Hermione I**“LaFayette” (12 km), s-XXII

**Ijiraq**(12 km), a-107

**Camilla I**“Lavinia” (11 km), p-1P

**Halley’s Comet**(11 km), a-26858

**Misterrogers**(10 km), s-XXVIII

**Erriapus**(10 km), p-5335

**Damocles**(10 km), etc.

*Fictional Examples*: The asteroids in the 1998 disaster films

*Armageddon*and

*Deep Impact*were both in this range.

__Size-S: Cruithne Class Planetoids__

*Picture gallery*

*Size*: 1-10 km

*Description*: Planetoids larger than 1 km in diameter are massive enough to be held together by gravity. There are roughly 750,000 planetoids of this size in the Main Asteroid Belt alone. An object this size or larger would cause global catastrophe and a high death toll if it struck the Earth.

*Solar System Examples*: j-XVII

**Callirrhoe**(9 km), n-XIV

**S/2004N1**“Polyphemus” (9 km), o-20461

**Dioretsa**(9 km), a-4261

**Gekko**(8 km), a-1602

**Indiana**(8 km), a-2410

**Morrison**(9 km), a-8161

**Newman**(8 km), a-9340

**Williamholden**(8 km), j-XVIII

**Themisto**(8 km), s-XXVII

**Skathi**(8 km), s-XLIV

**Hyrrokkin**(8 km), s-XXXV

**Daphnis**(7.8 km), a-3656

**Hemingway**(7 km), a-7012

**Hobbes**(7 km), a-30439

**Moe**(7 km), a-87 Sylvia II

**Remus**(7 km), a-2843

**Yeti**(7 km), j-XXVII

**Praxidike**(7 km), s-LII

**Tarqeq**(7 km), s-XXV

**Mundilfari**(7 km), s-XXI

**Narvi**(7 km), s-XXIII

**Suttungr**(7 km), s-XXX

**Thrymr**(7 km), s-XXXIX

**Bestla**(7 km), s-XLV

**Kari**(7 km), a-30441

**Curly**(6 km), a-130

**Elektra I**“Laodice” (6 km), a-30444

**Shemp**(6 km), p-9P

**Tempel 1**(6 km), s-XXXVII

**Bebhionn**(6 km), s-XLVII

**Skoll**(6 km), s-LI

**Greip**(6 km), s-L

**Jarnsaxa**(6 km), s-XXXVIII

**Bergelmir**(6 km), s-XLIII

**Hati**(6 km), s-XXXVI

**Aegir**(6 km), s-XLVIII

**Surtur**(6 km), s-XLVI

**Loge**(6 km), s-XLII

**Fornjot**(6 km), s-

**S/2004S7**“Inyukchuk” (6 km), s- S

**/2004S13**“Hulk” (6 km), s- S

**/2006S1**“Goliath” (6 km), s-

**S/2006S3**“Giganta” (6 km), s-

**S/2007S2**“Galactus” (6 km), i-4179

**Toutatis**(5.4 km), j-XIX

**Megaclite**(5.4 km), i-3753

**Cruithne**(5 km), a-2991

**Bilbo**(5 km), a-30440

**Larry**(5 km), a-2782

**Leonidas**(5 km), a-7010

**Locke**(5 km), a-12931

**Mario**(5 km), a-22540

**Mork**(5 km), j-XXIV

**Iocaste**(5 km), j-XX

**Taygete**(5 km), j-XXIII

**Kalyke**(5 km), s-XL

**Farbauti**(5 km), s-

**S/2004S12**“Hagrid” (5 km), s-

**S/2007S3**“Bigfoot” (5 km), a-5535

**Annefrank**(4.8 km), p-2P

**Encke’s Comet**(4.8 km), p-19P

**Borrelly’s Comet**(4.8 km), s-XXXIII

**Pallene**(4.4 km), c-C/1996B2

**Comet Hyakutake**(4.2 km), a-9777

**Enterprise**(4 km), a-9000

**Hal**(4 km), a-13681

**Monty Python**(4 km), a-17058

**Rocknroll**(4 km), a-118401

**LINEAR**(4 km), j-XLV

**Helike**(4 km), j-XXII

**Harpalyke**(4 km), j-XXX

**Hermipipe**(4 km), j-XXIX

**Thyone**(4 km), j-XXI

**Chaldene**(4 km), j-XLI

**Aoede**(4 km), j-XLVII

**Eukelade**(4 km), j-XXVI

**Isonoe**(4 km), j-XXVII

**Autonoe**(4 km), j-LIII

**Dia**(4 km), j-

**S/2003J5**“Meganfox” (4 km), s-XLI

**Fenrir**(4 km), s-

**S/2004S17**“Andre” (4 km), s-

**S/2004S6**“Maverick” (unconfirmed) (4 km), p-81P

**Wild 2**(4 km), a-7968

**Elst-Pizarro**(3.8 km), i-53319

**1999JM8**“Homer” (3.5 km), p-17P

**Comet Holmes**(3.4 km), s-XXXII

**Methone**(3.2 km), a-18610

**Arthurdent**(3 km), a-111818

**Deforest**(3 km), i-20037

**Duke**(3 km), a-17059

**Elvis**(3 km), a-29391

**Knight**(3 km), a-13404

**Norris**(3 km), a-13070

**Seanconnery**(3 km), j-XLVI

**Carpo**(3 km), j-XXXIII

**Euanthe**(3 km), j-XXXI

**Aitne**(3 km), j-XXV

**Erinome**(3 km), j-XXXII

**Eurydome**(3 km), j-XXXIX

**Hegemone**(3 km), j-XLIII

**Arche**(3 km), i-1620

**Geographos**(2.6 km), a-9969

**Braille**(2.6 km), s-XXXIV

**Polydeuces**(2.6 km), i-4055

**Magellan**(2.5 km), i-6178

**1986DA**“Zoolander” (2.3 km), i-163693

**Atira**(2 km), a-46610

**Bésixdouze**(2 km), m-5261

**Eureka**(2 km), a-178008

**Picard**(2 km), a-15907

**Robot**(2 km), j-XXXIV

**Euporie**(2 km), j-XLII

**Thelxinoe**(2 km), j-XXXV

**Orthosie**(2 km), j-XL

**Mneme**(2 km), j-L

**Herse**(2 km), j-XXXVII

**Kale**(2 km), j-XLIV

**Kallichore**(2 km), j-XXXVIII

**Pasithee**(2 km), j-XLIX

**Kore**(2 km), j-XLVIII

**Cyllene**(2 km), j-XXXVI

**Sponde**(2 km), j-

**S/2003J2**“Nichelle” (2 km), j-

**S/2003J3**“Sigourney” (2 km), j-

**S/2003J4**“Uma” (2 km), j-

**S/2003J9**“Bloodgood” (2 km), j-

**S/2003J10**“Scarlett” (2 km), j-

**S/2003J15**“Saldana” (2 km), j-

**S/2003J16**“Glau” (2 km), j-

**S/2003J18**“Portman” (2 km), j-

**S/2003J19**“Brigittehelm” (2 km), j-

**S/2003J23**“Jolie” (2 km), j-LI

**S/2010J1**“Carrie” (2 km), s-XLIX

**Anthe**(2 km), i-1862

**Apollo**(1.6 km), i-1221

**Amor**(1.5 km), i-1566

**Icarus**(1.4 km), a-243 Ida I

**Dactyl**(1.4 km), d-

**Shoemaker-Levy 9**(1.4 km before splintering and colliding with Jupiter in July 1994), a-132524

**APL**(1.2 km), i-3908

**Nyx**(1 km), m-121514

**1999UJ7**“Hajus” (1 km), m-101429

**1998VF31**“Dejah” (1 km), m-

**2007NS2**“Tarkas” (1 km), j-

**S/2003J12**“LeBrock” (1 km), j-LII

**S/2010J2**“Torres” (1 km), j-

**S/2011J1**“Faywray” (1 km), j-

**S/2011J2**“Jovovich” (1 km), etc.

*Description*: There are roughly 25 million planetoids of this size in the Main Asteroid Belt alone, and many more than that elsewhere in our Solar System. At this size and below, objects are too small to be held together by their own gravity, so they tend to be solid fragments, not “rubble piles.” An impact to Earth from an object this size would trigger (at least) localized catastrophes such as earthquakes and tsunamis. For the sake of comparison, Egypt’s Great Pyramid of Giza has a mean geometric diameter of about 169 m.

*Solar System Examples*: p-14827

**Hypnos**(900 m), s-LIII

**Aegaeon**(500 m), i-2062

**Aten**(450 m), s-

**S/2009S1**“Yaeger” (400 m), i-4660

**Nereus**(330 m), i-

**2005YU55**“Diddle” (325 m), e-

**2010TK7**“Scout” (300 m), i-25143

**Itokawa**(300 m), i-

**2010SO16**“Samwise” (250 m), i-85585

**Mjolnir**(180 m), i-99942

**Apophis**(135 m), etc. This size class also includes the larger “propeller” moonlets in Saturn’s A-Ring, including “Blériot” (400 m), “Earhart” (300 m), “Santos-Dumont” (100 m), etc.

__Size-U: Tunguska Class Planetoids__

*Picture gallery*

*Size*: 10-100 m

*Description*: An object this size is large enough that the Earth’s atmosphere would create a massive fireball that would vaporize on impact, creating a sizeable crater. The asteroid or comet that caused the Tunguska Event in an isolated area of Siberia in 1908 was probably about 50 m in diameter. (It was the largest land impact event in Earth’s recent history, exploding at an altitude of 5-10 km with a force equal to 5-30 megatons of TNT, or 1,000 times as powerful as the atomic bomb dropped on Hiroshima. It knocked over an estimated 80 million trees covering 2,150 square km.) The largest object to hit the Earth in a given century is typically about 20 m.

*Solar System Examples*: This size class includes near-Earth asteroids i-

**2002AA29**“Robin” (60 m) and i-

**2003YN107**“Tonto” (20 m), both of which orbit in a near 1:1 resonance with the Earth. It also includes many of the smaller, mostly unnamed “propeller” moonlets in Saturn’s rings.

**METEOROIDS**

*Picture gallery*

__Size-V: Extra Large Meteoroids__

*Size*: 1-10 m

*Description*: If an object this collides with Earth, it will create a very bright fireball. Part of it will survive entry and impact the surface, creating a small crater or pit. The largest object to hit the Earth in a given year is typically about 4 m.

*Solar System Examples*: i-

**2006RH120**“Bucky” (5 m), a tiny asteroid with an orbit very close to Earth’s, became a temporary satellite (one with an unstable orbit) of Earth from September 2006 to June 2007. It is predicted to next make a close approach to Earth in 2028, although its small size makes predictions about its orbit uncertain.

*Fictional Example*:

**B-612**, the home-world of the Little Prince from Antoine de Saint-Exupéry’s wonderful children’s book Le Petit Prince was about the size of a house, which would put it in this size class. By the way, the book inspired the names of two real-life planetoids: asteroid 46610 Bésixdouze, whose name is French for "B six twelve" (the asteroid’s number, 46610, is written B612 in hexadecimal notation); and Petit-Prince, the moon of asteroid 45 Eugenia.

__Size-W: Large Meteoroids__

*Size*: 10 cm-1 m

*Description*: An object this size that collides with Earth’s atmosphere will penetrate below 50 km altitude, creating a very bright fireball. Part of the meteoroid may survive entry. The largest object to hit the Earth in a given day is typically about 40 cm.

__Size-X: Medium Meteoroids__

*Size*: 1-10 cm

*Description*: An object this size that collides with Earth’s atmosphere will create a bright fireball. Part of the meteoroid may survive entry.

__Size-Y: Small Meteoroids__

*Size*: 1 mm-1 cm

*Description*: Under the right circumstances, objects of this size will burn bright enough to be visible to the naked eye if they collide with Earth’s atmosphere. They will not survive entry.

__Size-Z: Micrometeoroids__

*Size*: 100 μm-1 mm

*Description*: Objects this size will not be visible except by radar if they collide with Earth’s atmosphere, and they will not survive entry. Impacts from micrometeoroids pose a significant hazard to space travel.

**SMALLER OBJECTS**

__Cosmic Dust__

*Size*: <100 μm

*Description*: Cosmic dust is relatively plentiful throughout the Solar System and interstellar space. These objects are small enough that they float to the surface of the Earth rather than incinerating, adding more than 30,000 tons per year to the Earth’s mass.

__Molecules__

*Description*: Even smaller than cosmic dust are the individual atoms and molecules that the Sun emits as “solar wind.” Harnessing these particles with giant “sails” may aid in future space travel.

**Are we there yet?**

According to the Minor Planet Center, we have already identified over 80 million substellar celestial objects in our own Solar System, and many more await discovery. With such a large and diverse group, we need robust ways to categorize them. In this two-part article, I’ve described sensible ways to classify substellar celestial objects according to their size, orbital characteristics and location in the Solar System. There are many other ways to classify such objects, including color, albedo, composition, internal structure, age, habitability, and so on. The ones that I discussed, however, address the issues raised by the IAU’s flawed 2006 definition of “planet,” and thus the issues of most immediate concern.

Most importantly, I hope that you’ll agree with my proposal that we define the “planet” and related terms based on size alone, and that it makes sense to look at the issue of planethood as a sliding scale that embraces the diversity of these objects rather than as a simple “yes-or-no” question.

I figure you should make the boundary of D and E composition rather then mass.

ReplyDeletehttp://impact.ese.ic.ac.uk/cgi-bin/crater.cgi?dist=100&distanceUnits=1&diam=60&diameterUnits=1&pdens=&pdens_select=3000&vel=20&velocityUnits=1&theta=80&wdepth=&wdepthUnits=1&tdens=2750

ReplyDeleteOh and For class U, asteroids...

The atmosphere will slow them down.

Thanks, mate!

DeleteThis comment has been removed by the author.

ReplyDeleteCan you say me, please, in which comic is stated?

ReplyDeleteAccording to famous comic book artist John Byrne, DC Comics' Apokolips and New Genesis are planets "much smaller than our Moon."

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