For millennia, human beings stared up at the night sky and were held in awe by the Moon.
To many ancient cultures, it represented a deity, and its cycles were
accorded divine significance. By the time of Classical Antiquity and the
Middle Ages, the Moon was considered to be a heavenly body that orbited
Earth, much like the other known planets of the day (Mercury, Venus,
Mars, Jupiter, and Saturn).
However, our understanding of moons was revolutionized when in 1610, astronomer Galileo Galilei
pointed his telescope to Jupiter and noticed ” four wandering stars”
around Jupiter. From this point onward, astronomers have come to
understand that planets other than Earth can have their own moons – in
some cases, several dozen or more. So just how many moons are there in
the Solar System?
In truth, answering that question requires a bit of a clarification
first. If we are talking about confirmed moons that orbit any of the
planets of the Solar System (i.e. those that are consistent with the
definition adopted by the IAU in 2006), then we can say that there are currently 173 known moons. If, however, we open the floor to dwarf planets that have objects orbiting them, the number climbs to 182.
The moons, several minor planets and comets of the Solar System, shown to scale. Credit: Antonio Ciccolella |
However, over 200 minor-planet moons
have also been observed in the Solar System (as of Jan. 2012). This
includes the 76 known objects in the asteroid belt with satellites, four
Jupiter Trojans, 39 near-Earth objects (two with two satellites each),
14 Mars-crossers, and 84 natural satellites of Trans-Neptunian Objects.
And some 150 additional small bodies have been observed within the rings
of Saturn. If we include all these, then we can say that the Solar
System has 545 known satellites.
Inner Solar System:
The planets of the Inner Solar system – Mercury, Venus, Earth and Mars – are all terrestrial planets,
which means that they are composed of silicate rock and minerals that
are differentiated between a metallic core and a silicate mantle and
crust. For a number of reasons, few satellites exist within this region
of the Solar System.
All told, only three natural satellites exist orbiting planetary
bodies in the Inner Solar System – Earth and Mars. While scientist
theorize that there were moons around Mercury and Venus in the past, it
is believed that these moons impacted on the surface a long time ago.
The reason for this sparseness of satellites has a lot to do with the
gravitational influence of the Sun.
Both Mercury and Venus are too close to the Sun (and in Mercury’s
case, too weak in terms of its own gravitational pull) to have grabbed
onto a passing object, or held onto rings of debris in orbit that could
have coalesced to form a satellite over time. Earth and Mars were able
to retain satellites, but mainly because they are the outermost of the
Inner planets.
Earth has only the one natural satellite, which we are familiar with – the Moon.
With a mean radius of 1737 km and a mass of 7.3477 x 10²² kg, the Moon
is 0.273 times the size of Earth and 0.0123 as massive, which is quite
large for a satellite. It is also the second densest moon in our Solar
System (after Io), with a mean density of 3.3464 g/cm³.
Several theories have been proposed for the formation of the Moon.
The prevailing hypothesis today is that the Earth-Moon system formed as a
result of an impact between the newly-formed proto-Earth and a
Mars-sized object (named Theia)
roughly 4.5 billion years ago. This impact would have blasted material
from both objects into orbit, where it eventually accreted to form the
Moon.
Mars, meanwhile, has two moons – Phobos and Deimos.
Like our own Moon, both of the Martian moons are tidally locked to
Mars, so they always present the same face to the planet. Compared to
our Moon, they are rough and asteroid-like in appearance, and also much
smaller. Hence the prevailing theory that they were once asteroids that
were kicked out of the Main Belt by Jupiter’s gravity, and were then acquired by Mars.
The larger moon is Phobos, whose name comes from the Greek word which
means “fear” (i.e. phobia). Phobos measures just 22.7 km across and has
an orbit that places it closer to Mars than Deimos. Compared to Earth’s
own Moon — which orbits at a distance of 384,403 km away from our
planet — Phobos orbits at an average distance of only 9,377 km above
Mars.
Phobos and Deimos, photographed here by the Mars Reconnaissance Orbiter. Credit: NASA |
Mars’ second moon is Deimos, which takes its name from the Greek word
for panic. It is even smaller, measuring just 12.6 km across, and is
also less irregular in shape. Its orbit places it much farther away from
Mars, at a distance of 23,460 km, which means that Deimos takes 30.35
hours to complete an orbit around Mars.
These three moons are the sum total of moons to be found within the
Inner Solar System (at least, by the conventional definition). But
looking further abroad, we see that this is really just the tip of the
iceberg. To think we once believed that the Moon was the only one of its kind!
Outer Solar System:
Beyond the Asteroid Belt (and Frost Line),
things become quite different. In this region of the Solar System,
every planet has a substantial system of Moons; in the case of Jupiter
and Saturn, reaching perhaps even into the hundreds. So far, a total of
170 moons have been confirmed orbiting the Outer Planets, while several hundred more orbit minor bodies and asteroids.
Due to its immense size, mass, and gravitational pull, Jupiter has
the most satellites of any planet in the Solar System. At present, the
Jovian system includes 67 known moons, though it is estimated that it
may have up to 200 moons and moonlets (the majority of which are yet to
been confirmed and classified).
The four largest Jovian moons are known as the Galilean Moons (named after their discoverer, Galileo Galilei). They include: Io, the most volcanically active body in our Solar System; Europa, which is suspected of having a massive subsurface ocean; Ganymede, the largest moon in our Solar System; and Callisto, which is also thought to have a subsurface ocean and features some of the oldest surface material in the Solar System.
Illustration of Jupiter and the Galilean satellites. Credit: NASA |
Then there’s the Inner Group (or Amalthea group), which is made up of
four small moons that have diameters of less than 200 km, orbit at
radii less than 200,000 km, and have orbital inclinations of less than
half a degree. This groups includes the moons of Metis, Adrastea, Amalthea, and Thebe. Along with a number of as-yet-unseen inner moonlets, these moons replenish and maintain Jupiter’s faint ring system.
Jupiter also has an array of Irregular Satellites, which are
substantially smaller and have more distant and eccentric orbits than
the others. These moons are broken down into families that have
similarities in orbit and composition, and are believed to be largely
the result of collisions from large objects that were captured by
Jupiter’s gravity.
Similar to Jupiter, it is estimated that Saturn has at least 150 moons and moonlets, but only 53 of these moons
have been given official names. Of these, 34 are less than 10 km in
diameter and another 14 are between 10 and 50 km in diameter. However,
some of its inner and outer moons are rather large, ranging from 250 to
over 5000 km.
Traditionally, most of Saturn’s moons have been named after the
Titans of Greek mythology, and are grouped based on their size, orbits,
and proximity to Saturn. The innermost moons and regular moons all have
small orbital inclinations and eccentricities and prograde orbits.
Meanwhile, the irregular moons in the outermost regions have orbital
radii of millions of kilometers, orbital periods lasting several years,
and move in retrograde orbits.
A collage of Saturn (bottom left) and some of its moons: Titan, Enceladus, Dione, Rhea and Helene. Credit: NASA/JPL/Space Science Institute |
The Inner Large Moons, which orbit within the E Ring, includes the larger satellites Mimas Enceladus, Tethys, and Dione.
These moons are all composed primarily of water ice, and are believed
to be differentiated into a rocky core and an icy mantle and crust. The
Large Outer Moons, which orbit outside of the Saturn’s E Ring, are
similar in composition to the Inner Moons – i.e. composed primarily of
water ice and rock.
At 5150 km in diameter, and 1,350×1020 kg in mass, Titan
is Saturn’s largest moon and comprises more than 96% of the mass in
orbit around the planet. Titan is also the only large moon to have its
own atmosphere, which is cold, dense, and composed primarily of nitrogen
with a small fraction of methane. Scientists have also noted the
presence of polycyclic aromatic hydrocarbons in the upper atmosphere, as well as methane ice crystals.
The surface of Titan, which is difficult to observe due to persistent
atmospheric haze, shows only a few impact craters, evidence of
cryo-volcanoes, and longitudinal dune fields that were apparently shaped
by tidal winds. Titan is also the only body in the Solar System beside
Earth with bodies of liquid on its surface, in the form of methane–ethane lakes in Titan’s north and south polar regions.
Uranus has 27 known satellites, which are divided into the categories
of larger moons, inner moons, and irregular moons (similar to other gas
giants). The largest moons of Uranus are, in order of size, Miranda, Ariel, Umbriel, Oberon and Titania. These moons range in diameter and mass from 472 km and 6.7 × 1019 kg for Miranda to 1578 km and 3.5 × 1021 kg
for Titania. Each of these moons is particularly dark, with low bond
and geometric albedos. Ariel is the brightest while Umbriel is the
darkest.
A montage of Uranus’s moons (from left to right) – Ariel, Credit: NASA |
All of the large moons of Uranus are believed to have formed in the
accretion disc, which existed around Uranus for some time after its
formation, or resulted from the large impact suffered by Uranus early in
its history. Each one is comprised of roughly equal amounts of rock and
ice, except for Miranda which is made primarily of ice.
The ice component may include ammonia and carbon dioxide, while the rocky material is believed to be composed of carbonaceous material,
including organic compounds (similar to asteroids and comets). Their
compositions are believed to be differentiated, with an icy mantle
surrounding a rocky core.
Neptune has 14 known satellites, all but one of which are named after Greek and Roman deities of the sea (except for S/2004 N 1,
which is currently unnamed). These moons are divided into two groups –
the regular and irregular moons – based on their orbit and proximity to
Neptune. Neptune’s Regular Moons – Naiad, Thalassa, Despina, Galatea, Larissa, S/2004 N 1, and Proteus
– are those that are closest to the planet and which follow circular,
prograde orbits that lie in the planet’s equatorial plane.
Neptune’s irregular moons consist of the planet’s remaining satellites (including Triton).
They generally follow inclined eccentric and often retrograde orbits
far from Neptune. The only exception is Triton, which orbits close to
the planet, following a circular orbit, though retrograde and inclined.
Global Color Mosaic of Triton, taken by Voyager 2 in 1989. Credit: NASA/JPL/USGS |
In order of their distance from the planet, the irregular moons are Triton, Nereid,
Halimede, Sao, Laomedeia, Neso and Psamathe – a group that includes
both prograde and retrograde objects. With the exception of Triton and
Nereid, Neptune’s irregular moons are similar to those of other giant
planets and are believed to have been gravitationally captured by
Neptune.
With a mean diameter of around 2700 km ( mi) and a mass of 214080 ± 520 x 1017 kg, Triton is the largest of Neptune’s moons, and the only one large enough to achieve hydrostatic equilibrium
(i.e. is spherical in shape). At a distance of 354,759 km from Neptune,
it also sits between the planet’s inner and outer moons.
These moons make up the lion’s share of natural satellites found in
the Solar System. However, thanks to ongoing exploration and
improvements made in our instrumentation, satellites are being
discovered in orbit around minor bodies as well.
Dwarf Planets and Other Bodies:
As already noted, there are several dwarf planets, TNOs, and other
bodies in the Solar System that also have their own moons. These consist
mainly of the natural satellites that have been confirmed orbiting Pluto, Eris, Haumea and Makemake. With five orbiting satellites, Pluto has the most confirmed moons (though that may change with further observation).
The largest, and closest in orbit to Pluto, is Charon.
This moon was first identified in 1978 by astronomer James Christy
using photographic plates from the United States Naval Observatory
(USNO) in Washington, D.C. Beyond Charon lies the four other
circumbinary moons – Styx, Nix, Kerberos, and Hydra, respectively.
A portrait from the final approach of the New Horizons spacecraft to the Pluto system on July 11th, 2015. Credit: NASA-JHUAPL-SWRI. |
Nix and Hydra were discovered simultaneously in 2005 by the Pluto
Companion Search Team using the Hubble Space Telescope. The same team
discovered Kerberos in 2011. The fifth and final satellite, Styx, was
discovered by the New Horizons spacecraft in 2012 while capturing images
of Pluto and Charon.
Charon, Styx and Kerberos are all massive enough to have collapsed
into a spheroid shape under their own gravity. Nix and Hydra, meanwhile,
are oblong in shape. The Pluto-Charon system is unusual, since it is
one of the few systems in the Solar System whose barycenter lies above
the primary’s surface. In short, Pluto and Charon orbit each other,
causing some scientists to claim that it is a “double-dwarf system”
instead of a dwarf planet and an orbiting moon.
In addition, it is unusual in that each body is tidally locked to the
other. Charon and Pluto always present the same face to each other; and
from any position on either body, the other is always at the same
position in the sky, or always obscured. This also means that the
rotation period of each is equal to the time it takes the entire system
to rotate around its common center of gravity.
In 2007, observations by the Gemini Observatory
of patches of ammonia hydrates and water crystals on the surface of
Charon suggested the presence of active cryo-geysers. This would seem
indicate that Pluto does have a subsurface ocean that is warm in
temperature, and that the core is geologically active. Pluto’s moons are
believed to have been formed by a collision between Pluto and a
similar-sized body early in the history of the Solar System. The
collision released material that consolidated into the moons around
Pluto.
Comparison of Pluto with the other largest TNOs and with Earth (all to scale). Credit: NASA/Lexicon |
Coming in second is Haumea, which has two known moons – Hi’iaka and Namaka
– which are named after the daughters of the Hawaiian goddess. Both
were discovered in 2005 by Brown’s team while conducting observations of
Haumea at the W.M. Keck Observatory. Hi’iaka, which was initially
nicknamed “Rudolph” by the Caltech team, was discovered January 26th,
2005.
It is the outer and – at roughly 310 km in diameter – the larger and
brighter of the two, and orbits Haumea in a nearly circular path every
49 days. Infrared observations indicate that its surface is almost
entirely covered by pure crystalline water ice. Because of this, Brown
and his team have speculated that the moon is a fragment of Haumea that
broke off during a collision.
Namaka, the smaller and innermost of the two, was discovered on June
30th, 2005, and nicknamed “Blitzen”. It is a tenth the mass of Hi‘iaka
and orbits Haumea in 18 days in a highly elliptical orbit. Both moons
circle Haumea is highly eccentric orbits. No estimates have been made
yet as to their mass.
Eris has one moon called Dysnomia,
which is named after the daughter of Eris in Greek mythology, which was
first observed on September 10th, 2005 – a few months after the
discovery of Eris. The moon was spotted by a team using the Keck
telescopes in Hawaii, who were busy carrying out observations of the
four brightest TNOs (Pluto, Makemake, Haumea, and Eris) at the time.
Artist’s concept of the dwarf planet Eris and its only natural satellite, Dysnomia. Credit: NASA, ESA, Adolph Schaller (for STScI) |
In April of 2016, observations using the Hubble Space Telescope‘s
Wide Field Camera 3 revealed that Makemake had a natural satellite –
which was designated S/2015 (136472) 1 (nicknamed MK 2 by the discovery
team). It is estimated to be 175 km (110 mi) km in diameter and has a
semi-major axis at least 21,000 km (13,000 mi) from Makemake.
Largest and Smallest Moons:
The title for largest moon in the Solar System goes to Ganymede,
which measures 5262.4 kilometers (3270 mi) in diameter. This not only
makes it larger than Earth’s Moon, but larger even than the planet
Mercury – though it has only half of Mercury’s mass. As for the smallest
satellite, that is a tie between S/2003 J 9 and S/2003 J 12. These two
satellites, both of which orbit Jupiter, measure about 1 km (0.6 mi) in
diameter.
An important thing to note when discussing the number of known moons
in the Solar System is that the key word here is “known”. With every
passing year, more satellites are being confirmed, and the vast majority
of those we now know about were only discovered in the past few
decades. As our exploration efforts continue, and our instruments
improve, we may find that there are hundreds more lurking around out
there!
We have written many interesting articles about the moons of the Solar System here at Universe Today. Here’s What is the Biggest moon in the Solar System? What are the Planets of the Solar System?, How Many Moons Does Earth Have?, How Many Moons Does Mars Have?, How Many Moons Does Jupiter Have?, How Many Moons Does Saturn Have?, How Many Moons Does Uranus Have?, How Many Moons Does Neptune Have?
For more information, be sure to check out NASA’s Solar System Exploration page.
We have recorded a whole series of podcasts about the Solar System at Astronomy Cast. Check them out here.
Sources:
- NASA Solar System
- Wikipedia
- NASA Solar System Exploration
- Windows to the Universe
- Johnston’s Archive – Asteroids with Satellites
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