Jupiter is the fifth
planet
from the
Sun and the
largest planet within the
Solar System. It is a
gas
giant with a
mass slightly less than
one-thousandth that of the Sun but is two and a half times the mass
of all of the other planets in our Solar System combined. Jupiter
is classified as a gas giant along with
Saturn,
Uranus and
Neptune. Together, these four planets are sometimes
referred to as the
Jovian
planets.
The planet was known by
astronomers of
ancient times and was associated with the mythology and religious
beliefs of many cultures. The
Romans
named the planet after the
Roman god
Jupiter. When viewed from
Earth, Jupiter can reach an
apparent magnitude of −2.8, making it on
average the third-brightest object in the
night sky after the
Moon and
Venus. (
Mars can briefly
exceed Jupiter's brightness at certain points in its orbit.)
Jupiter is primarily composed of
hydrogen
with a quarter of its mass being
helium; it
may also have a rocky core of heavier elements. Because of its
rapid rotation, Jupiter's shape is that of an
oblate spheroid (it possesses a slight but
noticeable bulge around the equator). The outer atmosphere is
visibly segregated into several bands at different latitudes,
resulting in turbulence and storms along their interacting
boundaries. A prominent result is the
Great Red Spot, a giant storm that is known
to have existed since at least the 17th century when it was first
seen by telescope. Surrounding the planet is a faint
planetary ring system and a powerful
magnetosphere. There are also at least 63
moons, including the four large moons called the
Galilean moons that were first discovered by
Galileo Galilei in 1610.
Ganymede, the largest of these moons, has a
diameter greater than that of the planet
Mercury.
Jupiter has been explored on several occasions by
robotic spacecraft, most notably during
the early
Pioneer and
Voyager flyby missions and later by the
Galileo orbiter. The most
recent probe to visit Jupiter was the
Pluto-bound
New Horizons
spacecraft in late February 2007. The probe
used the gravity from Jupiter to
increase its speed. Future targets for exploration in the Jovian
system include the possible ice-covered liquid ocean on the moon
Europa.
Structure
Jupiter is one of the four
gas giants;
that is, it is not primarily composed of solid matter. It is the
largest planet in the Solar System, having a diameter of
142,984 km at its
equator. Jupiter's
density, 1.326 g/cm³, is the second highest of the gas giant
planets, but lower than any of the four
terrestrial planets.
Composition
Jupiter's upper atmosphere is composed of about 88–92% hydrogen and
8–12% helium by percent volume or fraction of gas
molecules (see table to the right). Since a helium
atom has about four times as much
mass as a
hydrogen atom, the
composition changes when described in terms of the proportion of
mass contributed by different atoms. Thus the
atmosphere is approximately 75%
hydrogen and 24% helium by mass, with the remaining one percent of
the mass consisting of other elements. The interior contains denser
materials such that the distribution is roughly 71% hydrogen, 24%
helium and 5% other elements by mass. The atmosphere contains trace
amounts of
methane,
water vapor,
ammonia, and
silicon-based compounds. There are also
traces of
carbon,
ethane,
hydrogen
sulfide,
neon,
oxygen,
phosphine, and
sulfur. The outermost layer of the atmosphere
contains
crystals of frozen ammonia. Through
infrared and
ultraviolet measurements, trace amounts of
benzene and other
hydrocarbons have also been found.
The atmospheric proportions of hydrogen and helium are very close
to the theoretical composition of the primordial
solar nebula. However, neon in the upper
atmosphere only consists of 20 parts per million by mass, which is
about a tenth as abundant as in the Sun. Helium is also depleted,
although only to about 80% of the Sun's helium composition. This
depletion may be a result of
precipitation of these elements
into the interior of the planet. Abundances of heavier inert gases
in Jupiter's atmosphere are about two to three times that of the
sun.
Based on
spectroscopy,
Saturn is thought to be similar in composition to
Jupiter, but the other gas giants
Uranus and
Neptune have relatively much less hydrogen
and helium. However, because of the lack of atmospheric entry
probes, high quality abundance numbers of the heavier elements are
lacking for the outer planets beyond Jupiter.
Mass
Approximate size comparison of Earth
and Jupiter, including the Great Red Spot
Jupiter is 2.5 times the
mass of all the other
planets in our Solar System combined — this is so massive that its
barycenter
with the
Sun actually lies above the
Sun's surface (1.068
solar radii from the Sun's center). Although
this planet dwarfs the Earth (with a diameter 11 times as great) it
is considerably less dense. Jupiter's volume is equal to 1,321
Earths, yet is only 318 times as massive. A "Jupiter mass"
(M
J or M
Jup) is often used as a unit to
describe masses of other objects, particularly
extrasolar planets and
brown dwarfs. So, for example, the extrasolar
planet
HD 209458 b has a mass of 0.69
M
J, while
CoRoT-7 b has a mass
of 0.015 M
J.
Theoretical models indicate that if Jupiter had much more mass than
it does at present, the planet would shrink. For small changes in
mass, the
radius would not change
appreciably, and above about four Jupiter masses the interior would
become so much more compressed under the increased gravitation
force that the planet's volume would actually
decrease
despite the increasing amount of matter. As a result, Jupiter is
thought to have about as large a diameter as a planet of its
composition and evolutionary history can achieve. The process of
further shrinkage with increasing mass would continue until
appreciable
stellar ignition is
achieved as in high-mass
brown dwarfs
around 50 Jupiter masses. This has led some astronomers to term it
a "failed star", although it is unclear whether or not the
processes involved in the formation of planets like Jupiter are
similar to the processes involved in the formation of multiple
star systems.
Although Jupiter would need to be about 75 times as massive to fuse
hydrogen and become a
star, the smallest
red dwarf is only about 30 percent larger
in radius than Jupiter. In spite of this, Jupiter still radiates
more heat than it receives from the Sun. The amount of heat
produced inside the planet is nearly equal to the total
solar radiation it receives. This additional
heat radiation is generated by the
Kelvin-Helmholtz mechanism
through
adiabatic contraction.
This process results in the planet shrinking by about 2 cm
each year. When it was first formed, Jupiter was much hotter and
was about twice its current diameter.
Internal structure
Jupiter is thought to consist of a dense
core with a mixture of elements, a
surrounding layer of liquid
metallic
hydrogen with some helium, and an outer layer predominantly of
molecular hydrogen. Beyond this
basic outline, there is still considerable uncertainty. The core is
often described as
rocky, but its
detailed composition is unknown, as are the properties of materials
at the temperatures and pressures of those depths (see below). In
1997, the existence of the core was suggested by gravitational
measurements, indicating a mass of from 12 to 45 times the Earth's
mass or roughly 3%–15% of the total mass of Jupiter.The presence of
a core during at least part of Jupiter's history is suggested by
models of planetary formation involving initial formation of a
rocky or icy core that is massive enough to collect its bulk of
hydrogen and helium from the
protosolar nebula. Assuming it did exist,
it may have shrunk as convection currents of hot liquid metallic
hydrogen mixed with the molten core and carried its contents to
higher levels in the planetary interior. A core may now be entirely
absent, as gravitational measurements are not yet precise enough to
rule that possibility out entirely.
The uncertainty of the models is tied to the error margin in
hitherto measured parameters: one of the rotational coefficients
(J
6) used to describe the planet's gravitational moment,
Jupiter's equatorial radius, and its temperature at 1 bar pressure.
The
JUNO mission, scheduled for
launch in 2011, is expected to narrow down the value of these
parameters, and thereby make progress on the problem of the
core.
The core region is surrounded by dense
metallic hydrogen, which extends outward
to about 78 percent of the radius of the planet. Rain-like droplets
of helium and neon precipitate downward through this layer,
depleting the abundance of these elements in the upper
atmosphere.
Above the layer of metallic hydrogen lies a transparent interior
atmosphere of
liquid hydrogen and
gaseous hydrogen, with the gaseous portion
extending downward from the cloud layer to a depth of about
1,000
km. Instead of a clear boundary or
surface between these different phases of hydrogen, there is
probably a smooth gradation from gas to liquid as one descends.This
smooth transition happens whenever the temperature is above the
critical temperature, which for
hydrogen is only 33
K (see
hydrogen).
The temperature and pressure inside Jupiter increase steadily
toward the core. At the
phase
transition region where liquid hydrogen—heated beyond its
critical point—becomes metallic, it is believed the temperature is
10,000 K
and the pressure is
200 GPa. The temperature at the core boundary is
estimated to be 36,000 K and the interior pressure is roughly
3,000–4,500 GPa.
Cloud layers
250 px
Jupiter is perpetually covered with clouds composed of ammonia
crystals and possibly
ammonium
hydrosulfide. The clouds are located in the
tropopause and are arranged into bands of
different
latitudes, known as tropical
regions. These are sub-divided into lighter-hued
zones and
darker
belts. The interactions of these conflicting
circulation patterns cause
storms and
turbulence.
Wind speeds of 100 m/s (360 km/h) are
common in zonal jets. The zones have been observed to vary in
width, color and intensity from year to year, but they have
remained sufficiently stable for astronomers to give them
identifying designations.
The cloud layer is only about 50 km deep, and consists of at
least two decks of clouds: a thick lower deck and a thin clearer
region. There may also be a thin layer of
water clouds underlying the ammonia
layer, as evidenced by flashes of
lightning detected in the atmosphere of Jupiter.
(Water is a
polar molecule that can
carry a charge, so it is capable of creating the charge separation
needed to produce lightning.) These electrical discharges can be up
to a thousand times as powerful as lightning on the Earth. The
water clouds can form thunderstorms driven by the heat rising from
the interior.
The orange and brown coloration in the clouds of Jupiter are caused
by upwelling compounds that change color when they are exposed to
ultraviolet light from the Sun. The
exact makeup remains uncertain, but the substances are believed to
be phosphorus, sulfur or possibly
hydrocarbons. These colorful compounds, known as
chromophores, mix with the warmer, lower
deck of clouds. The zones are formed when rising
convection cells form crystallizing ammonia
that masks out these lower clouds from view.
Jupiter's low
axial tilt means that the
poles constantly receive less
solar
radiation than at the planet's equatorial region.
Convection within the interior of the planet
transports more energy to the poles, however, balancing out the
temperatures at the cloud layer.
Great Red Spot and other storms
The best known feature of Jupiter is the Great Red Spot, a
persistent
anticyclonic storm located 22° south of the equator that is larger
than Earth. It is known to have been in existence since at least
1831, and possibly since 1665.
Mathematical models suggest that the
storm is stable and may be a permanent feature of the planet. The
storm is large enough to be visible through Earth-based
telescopes with an
aperture of or larger.
The
oval object
rotates counterclockwise, with a
period of about six days. The Great Red
Spot's
dimensions are 24–40,000 km ×
12–14,000 km. It is large enough to contain two or three
planets of Earth's diameter. The maximum altitude of this storm is
about 8 km above the surrounding cloudtops.
Storms such as this are common within the
turbulent atmospheres of
gas giants. Jupiter also has white ovals and brown
ovals, which are lesser unnamed storms. White ovals tend to consist
of relatively cool clouds within the upper atmosphere. Brown ovals
are warmer and located within the "normal cloud layer". Such storms
can last as little as a few hours or stretch on for
centuries.
Even before Voyager proved that the feature was a storm, there was
strong evidence that the spot could not be associated with any
deeper feature on the planet's surface, as the Spot rotates
differentially with respect to the rest of the atmosphere,
sometimes faster and sometimes more slowly. During its recorded
history it has traveled several times around the planet relative to
any possible fixed rotational marker below it.
In 2000, an atmospheric feature formed in the southern hemisphere
that is similar in appearance to the Great Red Spot, but smaller in
size. This was created when several smaller, white oval-shaped
storms merged to form a single feature—these three smaller white
ovals were first observed in 1938. The merged feature was named
Oval BA, and has been nicknamed Red Spot
Junior. It has since increased in intensity and changed color from
white to red.
Planetary rings
Jupiter has a faint
planetary ring
system composed of three main segments: an inner
torus of particles known as the halo, a relatively
bright main ring, and an outer gossamer ring. These rings appear to
be made of dust, rather than ice as is the case for Saturn's rings.
The main ring is probably made of material ejected from the
satellites
Adrastea and
Metis. Material that would normally fall back
to the moon is pulled into Jupiter because of its strong
gravitational pull. The orbit of the material veers towards Jupiter
and new material is added by additional impacts. In a similar way,
the moons
Thebe and
Amalthea probably produce the two distinct
components of the dusty gossamer ring.There is also evidence of a
rocky ring strung along Amalthea's orbit which may consist of
collisional debris from that moon.
Magnetosphere
Jupiter's broad
magnetic field is 14
times as strong as the Earth's, ranging from 4.2
gauss (0.42
mT) at
the equator to 10–14 gauss (1.0–1.4 mT) at the poles, making it the
strongest in the Solar System (with the exception of
sunspots). This field is believed to be generated by
eddy currents — swirling movements of
conducting materials—within the metallic hydrogen core. The field
traps a sheet of
ionized particles
from the
solar wind, generating a highly
energetic magnetic field outside the planet — the magnetosphere.
Electrons from this
plasma sheet
ionize the
torus-shaped cloud of
sulfur dioxide generated by the
tectonic activity on the moon
Io. Hydrogen particles from Jupiter's atmosphere
are also trapped in the magnetosphere. Electrons within the
magnetosphere generate a strong
radio
signature that produces bursts in the range of 0.6–30
MHz.
At about 75 Jupiter radii from the planet, the interaction of the
magnetosphere with the
solar wind
generates a
bow shock. Surrounding
Jupiter's magnetosphere is a
magnetopause, located at the inner edge of a
magnetosheath, where the planet's
magnetic field becomes weak and disorganized. The solar wind
interacts with these regions, elongating the magnetosphere on
Jupiter's
lee side and extending it outward
until it nearly reaches the orbit of Saturn. The four largest moons
of Jupiter all orbit within the magnetosphere, which protects them
from the solar wind.
The magnetosphere of Jupiter is responsible for intense episodes of
radio emission from the planet's polar
regions. Volcanic activity on the Jovian moon Io (see below)
injects gas into Jupiter's magnetosphere, producing a torus of
particles about the planet. As Io moves through this torus, the
interaction generates
Alfvén waves
that carry ionized matter into the polar regions of Jupiter. As a
result, radio waves are generated through a
cyclotron maser
mechanism, and the energy is transmitted out along a
cone-shaped surface. When the Earth intersects this cone, the radio
emissions from Jupiter can exceed the solar radio output.
Orbit and rotation
Jupiter is the only planet that has a
center of mass with the Sun that lies outside
the volume of the Sun, though by only 7% of the Sun's radius. The
average distance between Jupiter and the Sun is 778 million km
(about 5.2 times the average distance from the Earth to the Sun, or
5.2
AU) and it completes an orbit
every 11.86 years. This is two-fifths the orbital period of
Saturn, forming a 5:2
orbital resonance between the two largest
planets in the Solar System. The elliptical orbit of Jupiter is
inclined 1.31° compared to the Earth. Because of an
eccentricity of 0.048, the distance
from Jupiter and the Sun varies by 75 million km between
perihelion and
aphelion, or the nearest and most distant points of
the planet along the orbital path respectively.
The
axial tilt of Jupiter is relatively
small: only 3.13°. As a result this planet does not experience
significant
seasonal changes, in contrast to
Earth and Mars for example.
Jupiter's
rotation is the fastest of all
the Solar System's planets, completing a rotation on its
axis in slightly less than ten hours; this
creates an
equatorial bulge easily
seen through an Earth-based amateur
telescope. This rotation requires a
centripetal acceleration at the
equator of about 1.67 m/s², compared to the equatorial surface
gravity of 24.79 m/s²; thus the net acceleration felt at the
equatorial surface is only about 23.12 m/s². The planet is
shaped as an
oblate spheroid, meaning that
the
diameter across its
equator is longer than the diameter measured between
its
poles. On Jupiter, the
equatorial diameter is 9275 km longer than the diameter
measured through the poles.
Because Jupiter is not a solid body, its upper atmosphere undergoes
differential rotation. The
rotation of Jupiter's
polar atmosphere
is about 5 minutes longer than that of the equatorial
atmosphere; three systems are used as frames of reference,
particularly when graphing the motion of atmospheric features.
System I applies from the latitudes 10° N to 10° S; its
period is the planet's shortest, at 9h 50m 30.0s. System II applies
at all latitudes north and south of these; its period is 9h 55m
40.6s. System III was first defined by
radio astronomers, and corresponds to the
rotation of the planet's
magnetosphere; its period is Jupiter's
official rotation.
Observation
Jupiter is usually the fourth brightest object in the sky (after
the Sun, the
Moon and
Venus); however at times
Mars appears brighter than Jupiter. Depending
on Jupiter's position with respect to the
Earth, it can vary in visual magnitude from as bright
as −2.8 at
opposition down to
−1.6 during
conjunction with
the Sun. The
angular diameter of
Jupiter likewise varies from 50.1 to 29.8
arc
seconds. Favorable oppositions occur when Jupiter is passing
through perihelion, an event that occurs once per orbit. As Jupiter
approaches
perihelion in March 2011,
there will be a favorable opposition in September 2010.
The retrograde motion of an outer planet is caused by its relative
location with respect to the Earth.
Earth overtakes Jupiter every 398.9 days as it orbits the Sun, a
duration called the
synodic period.
As it does so, Jupiter appears to undergo
retrograde motion with respect
to the background stars. That is, for a period of time Jupiter
seems to move backward in the night sky, performing a looping
motion.
Jupiter's 12-year orbital period corresponds to the dozen
astrological signs of the
zodiac, and may have been the historical origin of
the signs. That is, each time Jupiter reaches opposition it has
advanced eastward by about 30°, the width of a zodiac sign.
Because the orbit of Jupiter is outside the Earth's, the
phase angle of Jupiter as viewed
from the Earth never exceeds 11.5°, and is almost always close to
zero. That is, the planet always appears nearly fully illuminated
when viewed through Earth-based telescopes. It was only during
spacecraft missions to Jupiter that crescent views ofthe planet
were obtained.
Research and exploration
Ground-based telescope research
In 1610,
Galileo Galilei discovered
the four largest
moons of Jupiter,
Io, Europa, Ganymede and
Callisto
(now known as the
Galilean moons)
using a telescope; thought to be the first observation of moons
other than Earth's. (It should be noted, however, that
Chinese historian of astronomy,
Xi Zezong, has claimed that
Gan
De, a Chinese astronomer, made the discovery of one of
Jupiter's moons in 362
BCE with the unaided eye.
If accurate, this would predate Galileo's discovery by nearly two
millennia.) Galileo's was also the first discovery of a
celestial motion not apparently centered
on the Earth. It was a major point in favor of
Copernicus' heliocentric theory of the motions of the
planets; Galileo's outspoken support of the Copernican theory
placed him under the threat of the
Inquisition.
During the 1660s, Cassini used a new telescope to discover spots
and colorful bands on Jupiter and observed that the planet appeared
oblate; that is, flattened at the poles. He was also able to
estimate the rotation period of the planet. In 1690 Cassini noticed
that the atmosphere undergoes
differential rotation.
The Great Red Spot, a prominent oval-shaped feature in the southern
hemisphere of Jupiter, may have been observed as early as 1664 by
Robert Hooke and in 1665 by
Giovanni Cassini, although this is
disputed. The pharmacist
Heinrich Schwabe produced the
earliest known drawing to show details of the Great Red Spot in
1831.
The Red Spot was reportedly lost from sight on several occasions
between 1665 and 1708 before becoming quite conspicuous in 1878. It
was recorded as fading again in 1883 and at the start of the
twentieth century.
Both
Giovanni Borelli and
Cassini made careful tables of the motions of the Jovian moons,
allowing predictions of the times when the moons would pass before
or behind the planet. By the 1670s, however, it was observed that
when Jupiter was on the opposite side of the Sun from the Earth,
these events would occur about 17 minutes later than expected.
Ole Rømer deduced that sight is not
instantaneous (a finding that Cassini had earlier rejected), and
this timing discrepancy was used to estimate the
speed of light.
In 1892,
E. E. Barnard observed
a fifth satellite of Jupiter with the refractor at Lick
Observatory
in California
. The discovery of this relatively small
object, a testament to his keen eyesight, quickly made him famous.
The moon was later named
Amalthea.
It was the last planetary moon to be discovered directly by visual
observation. An additional eight satellites were subsequently
discovered prior to the flyby of the
Voyager
1 probe in 1979.
In 1932,
Rupert Wildt identified
absorption bands of ammonia and methane in the spectra of
Jupiter.
Three long-lived anticyclonic features termed white ovals were
observed in 1938. For several decades they remained as separate
features in the atmosphere, sometimes approaching each other but
never merging. Finally, two of the ovals merged in 1998, then
absorbed the third in 2000, becoming
Oval
BA.
In 1955, Bernard Burke and
Kenneth
Franklin detected bursts of radio signals coming from Jupiter
at 22.2 MHz. The period of these bursts matched the rotation
of the planet, and they were also able to use this information to
refine the rotation rate. Radio bursts from Jupiter were found to
come in two forms: long bursts (or L-bursts) lasting up to several
seconds, and short bursts (or S-bursts) that had a duration of less
than a hundredth of a second.
Scientists discovered that there were three forms of radio signals
being transmitted from Jupiter.
- Decametric radio bursts (with a wavelength of tens of meters)
vary with the rotation of Jupiter, and are influenced by
interaction of Io with Jupiter's magnetic field.
- Decimetric radio emission (with wavelengths measured in
centimeters) was first observed by Frank
Drake and Hein Hvatum in 1959. The origin of this signal was
from a torus-shaped belt around Jupiter's equator. This signal is
caused by cyclotron radiation
from electrons that are accelerated in Jupiter's magnetic
field.
- Thermal radiation is produced by heat in the atmosphere of
Jupiter.
Exploration with space probes
Since 1973 a number of automated spacecraft have visited Jupiter.
Flights to other planets within the Solar System are accomplished
at a cost in
energy, which is described by
the net change in velocity of the spacecraft, or
delta-v. Reaching Jupiterfrom Earth requires a
delta-v of 9.2 km/s, which is comparable to the 9.7 km/s
delta-v needed to reach low Earth orbit. Fortunately,
gravity assists through planetary
flybys can be used to reduce
the energy required to reach Jupiter, albeit at the cost of a
significantly longer flight duration.
Flyby missions
Flyby missions
| Spacecraft |
Closest
approach |
Distance |
| Pioneer 10 |
December 3, 1973 |
130,000 km |
| Pioneer 11 |
December 4, 1974 |
34,000 km |
| Voyager 1 |
March 5, 1979 |
349,000 km |
| Voyager 2 |
July 9, 1979 |
570,000 km |
| Ulysses |
February 1992 |
409,000 km |
| February 2004 |
240,000,000 km |
| Cassini |
December 30, 2000 |
10,000,000 km |
| New Horizons |
February 28, 2007 |
2,304,535 km |
Voyager 1 took this photo of the
planet Jupiter on January 24, 1979 while still more than
25 million mi (40 million km) away.
Beginning in 1973, several spacecraft have performed planetary
flyby maneuvers that brought them within observation range of
Jupiter. The
Pioneer missions obtained the first close-up
images of Jupiter's atmosphere and several of its moons. They
discovered that the radiation fields in the vicinity of the planet
were much stronger than expected, but both spacecraft managed to
survive in that environment. The trajectories of these spacecraft
were used to refine the mass estimates of the Jovian system.
Occultations of the radio signals by the planet resulted in better
measurements of Jupiter's diameter and the amount of polar
flattening.
Six years later, the
Voyager missions vastly improved the
understanding of the
Galilean moons
and discovered Jupiter's rings. They also confirmed that the Great
Red Spot was anticyclonic. Comparison of images showed that the Red
Spot had changed hue since the
Pioneer missions, turning
from orange to dark brown. A torus of ionized atoms was discovered
along Io's orbital path, and volcanoes were found on the moon's
surface, some in the process of erupting. As the spacecraft passed
behind the planet, it observed flashes of lightning in the night
side atmosphere.
The next mission to encounter Jupiter, the
Ulysses solar
probe, performed a flyby maneuver in order to attain a polar orbit
around the Sun. During this pass the spacecraft conducted studies
on Jupiter's magnetosphere. However, since
Ulysses has no
cameras, no images were taken. A second flyby six years later was
at a much greater distance.
In 2000, the
Cassini probe,
en route to
Saturn, flew by Jupiter and provided some of the
highest-resolution images ever made of the planet. On December 19,
2000, the spacecraft captured an image of the moon
Himalia, but the resolution was too low to
show surface details.
The
New Horizons probe, en
route to
Pluto, flew by Jupiter for gravity
assist. Its closest approach was on February 28, 2007. The probe's
cameras measured plasma output from volcanoes on Io and studied all
four Galilean moons in detail, as well as making long-distance
observations of the outer moons
Himalia and
Elara. Imaging of the Jovian system began
September 4, 2006.
Galileo mission
So far the only spacecraft to orbit Jupiter is the
Galileo orbiter, which went into
orbit around Jupiter on December 7, 1995. It orbited the planet for
over seven years, conducting multiple flybys of all of the Galilean
moons and
Amalthea. The spacecraft
also witnessed the impact of
Comet Shoemaker-Levy 9 as it
approached Jupiter in 1994, giving a unique vantage point for the
event. However, while the information gained about the Jovian
system from
Galileo was extensive, its originally designed
capacity was limited by the failed deployment of its high-gain
radio transmitting antenna.
An atmospheric probe was released from the spacecraft in July 1995,
entering the planet's atmosphere on December 7. It parachuted
through 150 km of the atmosphere, collecting data for
57.6 minutes, before being crushed by the pressure to which it
was subjected by that time (about 22 times Earth normal, at a
temperature of 153 °C). It would have melted thereafter, and
possibly vaporized. The
Galileo orbiter itself experienced
a more rapid version of the same fate when it was deliberately
steered into the planet on September 21, 2003 at a speed of over
50 km/s, in order to avoid any possibility of it crashing into
and possibly contaminating Europa—a moon which has been
hypothesized to have the possibility of
harboring
life.
Future probes and canceled missions
NASA is planning a mission to study Jupiter in detail from a
polar orbit. Named
Juno, the spacecraft is planned to
launch by 2011.
The
Europa Jupiter System
Mission (EJSM) is a joint NASA
/ESA
proposal for
exploration of Jupiter and its moons. In February 2009 it
was announced that ESA/NASA had given this mission priority ahead
of the
Titan Saturn System
Mission. ESA's contribution will still face funding competition
from other ESA projects. Launch date will be around 2020. EJSM
consists of the NASA-led
Jupiter
Europa Orbiter, and the ESA-led
Jupiter Ganymede Orbiter.
Because of the possibility of subsurface liquid oceans on Jupiter's
moons Europa, Ganymede and Callisto, there has been great interest
in studying the icy moons in detail. Funding difficulties have
delayed progress. NASA's
JIMO (
Jupiter Icy Moons
Orbiter) was cancelled in 2005. A European
Jovian Europa Orbiter mission was also
studied. These missions were superseded by the Europa Jupiter
System Mission (EJSM).
Moons
Jupiter has 63 named
natural
satellites. Of these, 47 are less than 10 kilometres in
diameter and have only been discovered since 1975. The four largest
moons, known as the "
Galilean moons",
are Io, Europa, Ganymede and Callisto.
Galilean moons
The orbits of Io, Europa, and Ganymede, some of the largest
satellites in the Solar System, form a pattern known as a
Laplace resonance; for every four orbits
that Io makes around Jupiter, Europa makes exactly two orbits and
Ganymede makes exactly one. This resonance causes the
gravitational effects of the three large moons to
distort their orbits into elliptical shapes, since each moon
receives an extra tug from its neighbors at the same point in every
orbit it makes. The
tidal force from
Jupiter, on the other hand, works to circularize their
orbits.
The
eccentricity of their
orbits causes regular flexing of the three moons' shapes, with
Jupiter's gravity stretching them out as they approach it and
allowing them to spring back to more spherical shapes as they swing
away. This tidal flexing
heats the moons' interiors
via
friction. This is seen most
dramatically in the extraordinary
volcanic activity of innermost Io (which
is subject to the strongest tidal forces), and to a lesser degree
in the geological youth of
Europa's surface (indicating
recent resurfacing of the moon's exterior).
| The Galilean moons, compared to Earth's Moon |
| Name |
|
Diameter |
Mass |
Orbital radius |
Orbital period |
| km |
% |
kg |
% |
km |
% |
days |
% |
| Io |
|
3643 |
105 |
8.9×1022 |
120 |
421,700 |
110 |
1.77 |
7 |
| Europa |
|
3122 |
90 |
4.8×1022 |
65 |
671,034 |
175 |
3.55 |
13 |
| Ganymede |
|
5262 |
150 |
14.8×1022 |
200 |
1,070,412 |
280 |
7.15 |
26 |
| Callisto |
|
4821 |
140 |
10.8×1022 |
150 |
1,882,709 |
490 |
16.69 |
61 |
Classification of moons
Before the discoveries of the Voyager missions, Jupiter's moons
were arranged neatly into four groups of four, based on commonality
of their
orbital elements. Since
then, the large number of new small outer moons has complicated
this picture. There are now thought to be six main groups, although
some are more distinct than others.
A basic sub-division is a grouping of the eight inner regular
moons, which have nearly circular orbits near the plane of
Jupiter's equator and are believed to have formed with Jupiter. The
remainder of the moons consist of an unknown number of small
irregular moons with elliptical and inclined orbits, which are
believed to be captured asteroids or fragments of captured
asteroids. Irregular moons that belong to a group share similar
orbital elements and thus may have a common origin, perhaps as a
larger moon or captured body that broke up.
| Regular moons |
| Inner group |
The inner group of four small moons all 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. |
| Galilean moons |
These four moons, discovered by Galileo Galilei and by Simon Marius in parallel, orbit between 400,000
and 2,000,000 km, and include some of the largest moons in the
Solar System. |
| Irregular moons |
| Themisto |
This is a single moon belonging to a group of its own, orbiting
halfway between the Galilean moons and the Himalia group. |
| Himalia group |
A tightly clustered group of moons with orbits around
11,000,000–12,000,000 km from Jupiter. |
| Carpo |
Another isolated case; at the inner edge of the Ananke group,
it revolves in the direct sense. |
| Ananke group |
This group has rather indistinct borders, averaging
21,276,000 km from Jupiter with an average inclination of 149
degrees. |
| Carme group |
A fairly distinct group that averages 23,404,000 km from
Jupiter with an average inclination of 165 degrees. |
| Pasiphaë group |
A dispersed and only vaguely distinct group that covers all the
outermost moons. |
Interaction with the Solar System
Along with the Sun, the
gravitational
influence of Jupiter has helped shape the Solar System. The orbits
of most of the system's planets lie closer to Jupiter's
orbital plane than the Sun's
equatorial plane (
Mercury is the only planet that is closer
to the Sun's equator in orbital tilt), the
Kirkwood gaps in the
asteroid belt are mostly caused by Jupiter,
and the planet may have been responsible for the
Late Heavy Bombardment of the inner
Solar System's history.
In addition to its moons, Jupiter's gravitational field controls
numerous
asteroids that have settled into
the regions of the
Lagrangian
points preceding and following Jupiter in its orbit around the
sun. These are known as the
Trojan
asteroids, and are divided into
Greek and
Trojan "camps" to
commemorate the
Iliad. The first of
these,
588 Achilles, was discovered by
Max Wolf in 1906; since then more than two
thousand have been discovered. The largest is
624 Hektor.
The majority of
short-period
comets belong to the Jupiter family—defined as comets with
semi-major axes smaller than
Jupiter's. Jupiter family comets are believed to form in the
Kuiper belt outside the orbit of
Neptune. During close encounters with Jupiter their orbits are
perturbed into a smaller period and then circularized by regular
gravitational interaction with the Sun and Jupiter.
Impacts
Jupiter has been called the Solar System's vacuum cleaner, because
of its immense
gravity well and
location near the inner Solar System. It receives the most frequent
comet impacts of the Solar System's planets. It was thought that
the planet served to partially shield the inner system from
cometary bombardment. However, recent computer simulations suggest
that Jupiter doesn't cause a net decrease in the number of comets
that pass through the inner Solar System, as its gravity perturbs
their orbits inward in roughly the same numbers that it accretes or
ejects them. This topic remains controversial among current
astronomers, as some believe it draws comets towards Earth from the
Kuiper Belt while others believe that
Jupiter protects Earth from the alleged
Oort
Cloud.
A 1997 survey of historical astronomical drawings suggested that
the astronomer
Cassini may
have recorded an impact scar in 1690. The survey determined eight
other candidate observations had low or no possibilities of being
an impact.
During the period July 16, 1994 to July 22,
1994, over 20 fragments from the comet
Shoemaker-Levy 9 (SL9,
formally designated D/1993 F2) collided with Jupiter's southern
hemisphere
, providing the first direct observation of a
collision between two Solar System objects. This impact
provided useful data on the composition of Jupiter's
atmosphere.
On July 19, 2009, an
impact site
was discovered at approximately 216 degrees longitude in System 2.
This impact left behind a black spot in Jupiter's atmosphere,
similar in size to
Oval
BA. Infrared observation showed a bright spot where the impact
took place, meaning the impact warmed up the lower atmosphere in
the area near Jupiter's south pole.
Possibility of life
In 1953, the
Miller-Urey
experiment demonstrated that a combination of lightning and the
chemical compounds that existed in the atmosphere of a primordial
Earth could form organic compounds (including
amino acids) that could serve as the building
blocks of life. The simulated atmosphere included water, methane,
ammonia and molecular hydrogen; all molecules still found in the
atmosphere of Jupiter. However, the atmosphere of Jupiter has a
strong vertical air circulation, which would carry these compounds
down into the lower regions. The higher temperatures within the
interior of the atmosphere breaks down these chemicals, which would
hinder the formation of Earth-like life.
It is considered highly unlikely that there is any Earth-like
life on Jupiter, as there is
only a small amount of water in the atmosphere and any possible
solid surface deep within Jupiter would be under extraordinary
pressures. However, in 1976, before the
Voyager missions, it was hypothesized that
ammonia- or
water-based life could evolve in
Jupiter's upper atmosphere. This hypothesis is based on the ecology
of terrestrial seas which have simple
photosynthetic plankton at the top level,
fish
at lower levels feeding on these creatures, and marine
predators which hunt the fish.
Ancient mythology
The planet Jupiter has been known since ancient times. It is
visible to the naked eye in the night sky and can occasionally be
seen in the daytime when the sun is low.
To the Babylonians
, this object represented their god Marduk. They used the roughly 12-year orbit of
this planet along the
ecliptic to define
the
constellations of their
zodiac.
The Romans named it after
Jupiter ( ) (also called
Jove), the principal
god of
Roman
mythology, whose name comes from the
Proto-Indo-European
vocative form
*dyeu
ph2ter, meaning "god-father." The
astronomical symbol for the planet,
, is a stylized representation of the
god's lightning bolt. The original Greek deity,
Zeus, adopted by Romans, supplies the root
zeno-, used to form some Jupiter-related words, such as
zenographic.
Jovian is the
adjectival form of
Jupiter. The older adjectival form
jovial, employed by
astrologers in the
Middle Ages, has come
to mean "happy" or "merry," moods ascribed to
Jupiter's astrological
influence.
The
Chinese, Korean
, Japanese,
and Vietnamese
referred to the planet as the wood star,
木星, based on the Chinese Five Elements. The
Greeks called it Φαέθων,
Phaethon, "blazing." In
Vedic Astrology, Hindu astrologers named the planet
after
Brihaspati, the religious teacher
of the gods, and often called it "
Guru," which
literally means the "Heavy One." In the
English language,
Thursday is rendered as Thor's day, with
Thor being associated with the planet Jupiter in
Germanic mythology.
See also
References
- As of 2008, the largest known planet outside the Solar System
is TrES-4.
- – See section 3.4.
- ( Horizons)
- See for example: That particular word has been in use since at
least 1966. See:
Further reading
External links
- —A simulation of the 62 Jovian moons.
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