Great Red Spot

The Great Red Spot is a persistent anticyclonic storm Storm

A storm is any disturbed state of a planet's atmosphere [i], especially affect ...

on the planet Planet

The International Astronomical Union [i] , the official scientific [i] body for astronomical [i] nomenclature [i] ...

Jupiter Jupiter

Jupiter is the fifth planet [i] from the Sun [i] and the largest [i] within the solar system [i] ...

, 22? south of the equator, which has lasted at least 340 years. The storm is large enough to be visible through Earth Earth

Earth is the third planet [i] in the solar system [i] in terms of distance from the Sun [i], and the fi ...

-based telescope Telescope

The word "telescope" usually refers to optical telescope [i]s, but there are telescopes for most of the ...

s. It was probably first observed by Cassini Giovanni Domenico Cassini

Giovanni Domenico Cassini was an Italian [i] astronomer [i], engineer [i], and astrologer [i]. ...

, who described it around 1665. This dramatic view of Jupiter's Great Red Spot and its surroundings was obtained by Voyager 1 Voyager 1

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The Great Red Spot is a persistent anticyclonic storm Storm

A storm is any disturbed state of a planet's atmosphere [i], especially affect ...

on the planet Planet

The International Astronomical Union [i] , the official scientific [i] body for astronomical [i] nomenclature [i]...

Jupiter Jupiter

Jupiter is the fifth planet [i] from the Sun [i] and the largest [i] within the solar system [i] ...

, 22� south of the equator, which has lasted at least 340 years. The storm is large enough to be visible through Earth Earth

Earth is the third planet [i] in the solar system [i] in terms of distance from the Sun [i], and the fi ...

-based telescope Telescope

The word "telescope" usually refers to optical telescope [i]s, but there are telescopes for most of the ...

s. It was probably first observed by Cassini Giovanni Domenico Cassini

Giovanni Domenico Cassini was an Italian [i] astronomer [i], engineer [i], and astrologer [i]....

, who described it around 1665.

This dramatic view of Jupiter's Great Red Spot and its surroundings was obtained by Voyager 1 Voyager 1

The Voyager 1 spacecraft is an 815-kilogram unmanned probe of the outer solar system [i] and beyond, ...

on February 25, 1979, when the spacecraft was 9.2 million km from Jupiter. Cloud details as small as 160 km across can be seen here. The colorful, wavy cloud pattern to the left of the Red Spot is a region of extraordinarily complex and variable wave motion. To give a sense of Jupiter's scale, the white oval storm directly below the Great Red Spot is approximately the same diameter as Earth Earth

Earth is the third planet [i] in the solar system [i] in terms of distance from the Sun [i], and the fi ...

.

The oval object rotates Rotation

Rotation is the movement of an object in a circular motion....

counterclockwise Clockwise and counterclockwise

A clockwise motion is one that proceeds 'like the clock [i]'s hands': from the top to the right, then do ...

, with a period of about 6 day Day

A day is a unit [i] of time [i] equal to 24 hour [i]s. ...

s. The Great Red Spot's dimension Dimension

In common usage, a dimension is a parameter [i] or measurement [i] required to define the characteristi ...

s are 24–40,000 km × 12–14,000 km. It is large enough to contain two or three planets of Earth size. The cloud Cloud

A cloud is a visible mass of condensed droplets [i] or frozen crystal [i]s suspended in the atmosphere [i] ...

tops of this storm are about 8 km above the surrounding cloudtops.

Storms such as this are not uncommon within the turbulent Turbulence

In fluid dynamics [i], turbulence or turbulent flow is a flow regime characterized by chaotic, stochastic [i] ...

atmospheres Atmosphere

Atmosphere is the general name for a layer of gas [i]es that may surround a material body of sufficient ...

of gas giant Gas giant

A gas giant is a large planet [i] that is not primarily composed of rock [i] or other solid matter [i]...

s. Jupiter also has white ovals and brown ovals, which are lesser unnamed storms. White ovals tend to consist of relatively cool Heat

In physics [i], heat, symbolized by Q, is defined as energy in transit. ...

clouds within the upper atmosphere. Brown ovals are warmer and located within the "normal cloud layer". Such storms can last hours or centuries.

Before the Voyager missions, astronomers were highly uncertain of its nature. Many believed it to be a solid or liquid feature on Jupiter's surface.

Color and visibility

It is not known exactly what causes the Great Red Spot's reddish color. Theories supported by laboratory experiments suppose that the color may be caused by any of "complex organic molecules, red phosphorus, or yet another sulfur compound" , but a consensus has yet to be reached.

The Great Red Spot varies greatly in prominence, from almost brick-red to pale salmon, or even white. In fact, the Spot occasionally "disappears", becoming evident only through the Red Spot Hollow, which is its niche in the South Equatorial Belt Cloud pattern on Jupiter

The cloud pattern on Jupiter is the visible system of colored cloud [i] tops in the atmosphere [i] ...

. Interestingly, its visibility is apparently coupled to the SEB; when the Belt is bright white, the Spot tends to be dark, and when it is dark the Spot is usually light. These periods when the Spot is dark or light occur at irregular intervals; in the last 50 years the Spot was darkest from 1961-66, 1968-75, 1989-90, and 1992-93.

A smaller spot, designated Oval BA Oval BA

Oval BA is the South Temperate Belt [i] spot of the planet Jupiter [i]. ...

, formed recently from the merger of three white ovals, has turned reddish in color.

Longevity

The Great Red Spot appears at first to be remarkably stable, and most sources concur that it has been continuously observed for 300 years. However, the situation is more complex than that; the present Spot was first seen only in 1830, and well studied only after a prominent apparition in 1879. A long gap separates its period of current study after 1830 from its 17th-century discovery; whether the original Spot dissipated and reformed, or whether it faded, or even if the observational record was simply poor are all unknown.

Several factors may be responsible for its longevity, such as the fact that it never encounters solid surfaces over which to dissipate its energy and that its motion is driven by Jupiter's internal heat. Simulations suggest that the Spot tends to absorb smaller atmospheric disturbances.

At the start of 2004, the Great Red Spot was approximately half as large as it was 100 years ago. It is not known how long the Great Red Spot will last, or whether this is a result of normal fluctuations.

The Great Red Spot should not be confused with the Great Dark Spot Great Dark Spot

The Great Dark Spot was a dark spot on Neptune [i] similar to Jupiter's [i] Great Red Spot [i]. ...

, famously seen in the atmosphere of Neptune Neptune

Neptune is the eighth and outermost planet [i] in our solar system [i]. ...

by Voyager 2 Voyager 2

Voyager 2 is an unmanned [i] interplanetary [i] spacecraft [i]. ...

in 1989. The Great Dark Spot may have been an atmospheric hole rather than a storm, and it was no longer present as of 1994 .

Mechanics

As the hot gases that Jupiter's atmosphere Atmosphere

Atmosphere is the general name for a layer of gas [i]es that may surround a material body of sufficient ...

comprises rise from lower levels to higher levels, eddies form and converge together. A Coriolis force Coriolis effect

The Coriolis effect is an apparent deflection of a moving object in a rotating frame of reference [i].
...

forms and forces cooler air to fall back into a swirling motion that may be many kilometers in diameter. These eddies can last for a long time, because there is no solid surface to provide friction and colder cloud tops above the eddy allow little energy to escape by radiation. Once formed, such eddies are free to move, merging with or affecting the behaviour of other storm systems in the atmosphere. It is theorized that this mechanism formed the great red spot. According to this theory, many adjacent eddies are engulfed and merge with the spot, adding to the energy of the storm and contributing to its longevity.

Convergence

As of June 5 2006, the reported that the Great Red Spot and Oval BA Oval BA

Oval BA is the South Temperate Belt [i] spot of the planet Jupiter [i]. ...

might converge. The storms pass each other about every two years, but the passings of 2002 and 2004 did not produce anything exciting. But Dr. Amy Simon-Miller, of the Goddard Space Flight Center Goddard Space Flight Center

The Goddard Space Flight Center is a major NASA [i] space research laboratory established on May 1 [i], ...

, predicted the storms would have their closest passing on July 4. Simon-Miller had been working with Dr. Imke de Pater and Dr. Phil Marcus of UC Berkeley University of California, Berkeley

The University of California, Berkeley is the oldest and flagship campus of the ten-campus University of California [i] ...

, and a team of professional astronomers since April, studying the storms using the Hubble Space Telescope Hubble Space Telescope

The Hubble Space Telescope is a telescope [i] in orbit [i] around the Earth [i]....

. On July 20, the two storms were photographed passing each other by the Gemini Observatory Gemini Observatory

n>Gemini Observatory
[i]
...

. No convergence occurred.

References

Beatty, Kelly J., Peterson, Carolyn Collins, Chaiki, Andrew. "The New Solar System". Massachusetts: Sky Publishing Corporation, 1999.
Beebe, Reta. "Jupiter The Giant Planet" Smithsonian Institution 1997.
Peek Bertrand M. "The Planet Jupiter". London: Faber and Faber Limited, 1981.
Rogers, John H. "The Giant Planet Jupiter". Cambridge: Press Syndicate of the University of Cambridge, 1995
Youssef, Ashraf, Marcus, Philip S. "The dynamics of jovian white ovals from formation to merger". 1 November 2000: 74-93.