Io

Template:Infobox Planet Io (eye'-oe, Template:IPA2, Greek Ῑώ) is the innermost of the four Galilean moons of Jupiter. Io shines at magnitude 5.0 in the night sky. It is named after the Greek mythological figure Io, one of the many lovers of Zeus (who is also known as Jupiter in the Roman mythology). Io is the fourth largest moon in the Solar System.

Although the name "Io" was suggested by Simon Marius soon after its discovery in 1610, this name and the names of the other Galilean satellites fell into disfavor for a considerable time, and were not revived in common use until the mid-20th century. In much of the earlier astronomical literature, Io is simply referred to by its Roman numeral designation as "Jupiter I", or simply as "the first satellite of Jupiter".

History of observation and exploration

The moon Io is believed to have been discovered on 7 January, 1610 by Galileo. In his Mundus Jovialis, published in 1614, Simon Marius claimed to have discovered Io and the other moons of Jupiter in 1609, one week before Galileo's discovery. Galileo doubted this claim and catalogued the work of Marius as plagiarism.

In the middle of the 20th century observations were made suggesting that the polar regions of Io were red. The passage of the Pioneer 11 space probe in the 1970s, verified that the polar region had an orange color, contrasting with the whitish equator. However, Pioneer uncovered little other information on Io.

When the space probe, Voyager 1 sent its first images near Io in 1979, the scientists found that Io had almost no craters. While analyzing images, Voyager navigation engineer Linda Morabito noticed a "plume" emanating from the surface. Scientists found a relatively young surface caused by intense volcanic activity that covered any signs of craters. Voyager 1 was able to observe nine active volcanoes on the surface, and later Voyager 2 observed eight of the nine active volcanoes.

The Galileo spacecraft arrived at Jupiter in 1995, and flew by Io at the end of 1999. Galileo approached Io closer than any other probe, took many photographs, observed volcanoes erupting, and discovered that Io has a large iron core, like the rocky planets of the inner solar system.^[1]

Physical characteristics

Interior of Io

Internal Structure

Unlike most moons in the outer solar system, Io may be somewhat similar in bulk composition to the terrestrial planets, primarily composed of molten silicate rock. Recent data from the Galileo orbiter indicates that Io has a core of iron (perhaps mixed with iron sulfide), the core's radius being at least 900 km.^[2]Unlike the other Galilean satellites, Io has little or no water. This is probably because Jupiter was hot enough early in the evolution of the solar system to drive off the volatile elements in the vicinity of Io, but not hot enough to do so farther out. Io has the highest density out of all the moons in the Solar System.

Io exhibits extraordinary variations in color and brightness as shown in this color-enhanced image.

Surface Features

When Voyager 1 first returned images of Io in 1979, scientists expected to see numerous craters, the density of which across Io's surface would give clues to the moon's age. However, they were surprised to discover that Io's surface is almost completely lacking in impact craters, due to the tremendous amount of volcanic activity constantly reshaping the landscape. Since the surface features visible today were formed relatively recently, the Ionian surface is described as "young", as is the terrestrial surface. In contrast, celestial bodies with heavily cratered features, such as Earth's Moon, are considered to have "old" surfaces, since they have remained in their current state for billions of years. The unusual features and colors on Io's surface have led to its being compared to a rotten orange or to pizza.

In addition to volcanoes, Io's surface includes nonvolcanic mountains, numerous lakes of molten sulfur, calderas up to several kilometres deep, and extensive flows hundreds of kilometres long of low-viscosity fluid (possibly some form of molten sulfur or silicate). Sulfur and its compounds take on a wide range of colors and are responsible for Io's variegated appearance.

Tvashtar Paterae, a region of active volcanism on Io

Volcanism

Analysis of the Voyager images led scientists to believe that the lava flows on Io's surface were composed mostly of various compounds of molten sulfur. However, subsequent Earth-based infrared studies indicate that the flows are too hot for liquid sulfur; some of the hottest spots on Io may reach temperatures as high as 2000 K, 1300 K higher than the boiling point of sulfur, though the average is much lower, at around 130 K. One current theory is that Io's lavas are molten silicate rock. Recent Hubble Space Telescope observations indicate that the material may be rich in sodium. There may be a variety of different materials in different locations.^[3][4]

Galileo orbiter images reveal active volcanoes. The eruption in the top inset reaches 140km high, the other is 75km high.

Io is most noteworthy for its volcanic nature; it is the most volcanically active body in the Solar System. In February 2001, the largest recorded volcanic eruptions in the solar system occurred on Io.^[5] Like volcanoes on Earth, Ionian volcanoes emit sulfur and sulfur dioxide. Originally it was thought that many lava flows consisted of sulfurous substances. However, it is now believed that many of them are molten silicate rock as on the Earth.

The energy for this activity probably derives from tidal forces among Io, Jupiter, and the Jovian moons Europa and Ganymede. The three moons are locked into Laplace-resonant orbits such that Io orbits twice for each orbit of Europa, which in turn orbits twice for each orbit of Ganymede (Callisto will eventually join this resonant relationship as well); furthermore, Io always keeps the same face towards Jupiter. The gravitational interaction of Europa, Ganymede and Jupiter cause Io to "stretch" and "bend" by as much as 100 meters, a process which generates heat through internal friction.

Some of Io's volcanic plumes have been measured rising over 300 km above the surface before falling back, with material ejected from the surface at approximately one kilometre per second. The volcanic eruptions change rapidly; in just four months between the arrivals of Voyager 1 and Voyager 2, some eruptions stopped and others began. The deposits surrounding the vents also changed visibly during this time.

Another source of energy is Jupiter's magnetic field lines, which Io crosses, generating an electric current. Though not a large source of energy compared to the tidal heating, this current may carry more than 1,000 gigawatts with a potential of 400 kilovolts. It also strips ionized atoms from Io at the rate of a thousand kilograms per second. Due to the rapid rotation of Jupiter's magnetic field, these particles are swept along the orbit in front of Io where they form a torus of intense radiation around Jupiter that emits bright ultraviolet light. Particles escaping from this torus are partially responsible for Jupiter's unusually large magnetosphere, their outward pressure inflating it from within. Recent data from the Galileo orbiter indicate that Io might have its own magnetic field.^[6][2][7]

The location of Io with respect to the Earth and Jupiter has a strong influence on the Jovian radio emissions as seen from the earth: When Io is visible, radio signals from Jupiter increase considerably.

Atmosphere

Io has an extremely thin atmosphere consisting mainly of sulfur dioxide (SO₂) with a pressure of a billionth of an atmosphere. The thin Ioan atmosphere means any future lander-type probes sent to investigate Io will not need to be encased in an aeroshell-style heatshield, but instead, require retrorockets for a soft landing. The thin atmosphere also necessitates a rugged lander capable of enduring the strong Jovian radiation, which a thicker atmosphere would attenuate.

The same radiation (in the form of a plasma) strips the atmosphere so that it must be constantly replenished. The most dramatic source of SO₂ is volcanism, but the largest source is the sunlight-driven sublimation of SO₂ frozen on the surface. The atmosphere is largely confined to the equator, where the surface is warmest.

High resolution images of Io show an aurora-like glow. As on Earth, this is due to radiation hitting the atmosphere. Auroras usually occur near the magnetic poles of planets, but since Io does not have a magnetic field, and the atmosphere is thickest at the equator, Io's aurora is brightest there.

A summary of Io's atmosphere is contained in the chapter by McGrath et al. in the book "Jupiter: The Planet, Satellites and Magnetosphere" (2004).

See also

• Jupiter's moons in fiction
• List of geological features on Io
• List of mountains on Io
• List of paterae on Io

References

Template:reflist

External links

• Bill Arnett's Io webpage
• The Calendars of Jupiter
• The Conundrum Posed by Io's Minimum Surface Temperatures
• Io's Composition

Template:Moons of Jupiter Template:Natural satellites of the Solar System (compact) Template:Footer SolarSystem

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This natural satellite related article is a stub. You can help Orbiterwiki by expanding it. ↑ Template:cite journal ↑ 2.0 2.1 "NASA'S GALILEO FINDS GIANT IRON CORE IN JUPITER'S MOON IO" - May 3, 1996 NASA Press release. URL accessed Arpil 15, 2006 ↑ Roesler, F. L. et al, "Far-Ultraviolet Imaging Spectroscopy of Io's Atmosphere with HST/STIS" - January 15, 1999 Science Vol. 283. no. 5400, pp. 353 - 357. URL accessed Arpil 15, 2006. ↑ Geissler, P. E. et al, "Galileo Imaging of Atmospheric Emissions from Io" - August 6, 1999 Science Vol. 285. no. 5429, pp. 870 - 874. URL accessed April 15, 2006. ↑ Template:cite web ↑ Sarson, G. R. et al, "Magnetoconvection Dynamos and the Magnetic Fields of Io and Ganymede" - May 16, 1997, Science Vol. 276. no. 5315, pp. 1106 - 1108. URL accessed April 15, 2006. ↑ Krimigis, S. M. et al, "A nebula of gases from Io surrounding Jupiter" - 28 February, 2002 Nature 415, 994-996. URL accessed 15 April, 2006.