Portal:Jupiter
Opticals
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"This Hubble picture [on the left], taken on July 23, is the first full-disk natural-color image of Jupiter made with Hubble's new camera, the Wide Field Camera 3 (WFC3). It is the sharpest visible-light picture of Jupiter since the New Horizons spacecraft flew by that planet in 2007. Each pixel in this high-resolution image spans about 74 miles (119 km) in Jupiter's atmosphere. Jupiter was more than 370 million miles (600 million km) from Earth when the images were taken."[1]
"The dark smudge at bottom right is debris from a comet or asteroid that plunged into Jupiter's atmosphere and disintegrated."[1]
"In addition to the fresh impact, the image reveals a spectacular variety of shapes in the swirling atmosphere of Jupiter. The planet is wrapped in bands of yellow, brown, and white clouds. These bands are produced by the atmosphere flowing in different directions at various latitudes. When these opposing flows interact, turbulence appears."[1]
"Such data complement the images taken from other telescopes and spacecraft by providing exquisite details of atmospheric phenomena. For example, the image suggests that dark "barges" – tracked by amateur astronomers on a nightly basis – may differ both in form and color from barge features identified by the Voyager spacecraft. (The Great Red Spot and the smaller Red Oval are both out of view on the other side of the planet.)"[1]
"This color image is a composite of three separate color exposures (red, blue, and green) made by WFC3. Additional processing was done to compensate for asynchronous imaging in the color filters and other effects."[1]
"A Hubble picture [on the right in ultraviolet and visible lighy] from June 7, 2010, reveals a slightly higher altitude layer of white ammonia ice crystal clouds that appears to obscure the deeper, darker belt clouds of the SEB. The team predicts that these clouds should clear out in a few months."[2]
"Hubble also resolved a string of dark spots farther south of the vanished belt. Based on past observations, the Hubble Jupiter team expects to see similar spots appear in the SEB, right before its white clouds clear out in a few months."[2]
"The giant stormy planet Jupiter has gone through a makeover, as seen in the image below, taken nearly 11 months earlier. Several months ago the dark Southern Equatorial Belt (SEB) vanished. The last time this happened was in the early 1970s, when we didn't have powerful enough telescopes to study the change in detail."[2]
"This natural color planet portrait was taken in visible light with Hubble's new Wide Field Camera 3."[2]
References
- ↑ 1.0 1.1 1.2 1.3 1.4 M. Wong; H. B. Hammel; the Jupiter Impact Team (23 July 2009). Collision Leaves Giant Jupiter Bruised. Baltimore, Maryland USA: Space Telescope Science Institute. http://hubblesite.org/image/2573/news_release/2009-25. Retrieved 18 June 2018.
- ↑ 2.0 2.1 2.2 2.3 M.H. Wong; H.B. Hammel; A.A. Simon-Miller; the Jupiter Impact Science Team (7 June 2010). HST WFC3 Jupiter Image (June 7, 2010). Berkeley, California USA: University of Califoria. http://hubblesite.org/image/2745/news_release/2010-20. Retrieved 18 June 2018.
Trojan asteroids
Def. "the L4 and L5 Lagrange points of the Sun-Jupiter orbital configuration"[1] are called the Trojan points.
Def. "an asteroid occupying the Trojan points of the Sun-Jupiter system"[2] is called a Trojan asteroid.
References
- ↑ 65.94.44.124 (11 December 2010). Trojan point. San Francisco, California: Wikimedia Foundation, Inc. https://en.wiktionary.org/wiki/Trojan_point. Retrieved 2015-08-31.
- ↑ 65.94.44.124 (11 December 2010). Trojan asteroid. San Francisco, California: Wikimedia Foundation, Inc. https://en.wiktionary.org/wiki/Trojan_asteroid. Retrieved 2015-08-31.
Planetary astronomy
"Jupiter takes 12 years to make one trip around the Sun. These 12 images [on top] were taken between 2003 and 2015. At far left we see Jupiter in 2003, and the years proceed counterclockwise. The 2015 view is immediately above 2003."[1]
"Jupiter’s axial tilt is just 3° or nearly straight up and down, so seasons don’t exist. One part of the Jovian year is much the same as another. Still, as you can plainly see, the solar system’s biggest planet has plenty of weather."[2]
"Just look at the Great Red Spot or GRS. Through about 2008, it’s relatively large and pale but suddenly darkens in 2010 at the same time the South Equatorial Cloud Belt (the wide stripe of clouds above the Spot) disappears. If you look closely at the Spot from year to year, you’ll see another big change — it’s shrinking! The GRS has been dwindling for several decades, but it’s amazing how obvious the difference is in only a dozen years."[2]
"The planet gives off 1.6 times as much energy as it get from the Sun."[2]
"Fun to think that the light we see from Jupiter is reflected sunlight, but if we could view it with heat-sensing, infrared eyes, it would glow like an ember."[2]
"Images [second down] in the visible-light and infrared parts of the spectrum highlight the massive changes roiling the atmosphere of Jupiter. In the visible-light images on the left that were obtained by amateur astronomers, Jupiter can be seen "losing" a brown-colored belt south of the equator called the South Equatorial Belt (SEB) from 2009 to 2010. This belt returned in 2011 and was still present in 2012. From 2011 to January 2012, a belt north of the equator known as the North Equatorial Belt (NEB) can be seen to be thinning out. In 2011, it whitened to an extent not seen in over a century. In March of 2012, after the last picture in this series was taken, the northern belt began to darken again."[3]
"Scientists compared the visible-light data to data obtained in infrared wavelengths (middle and right columns), which show progressively deeper levels in the Jovian atmosphere. The infrared images were obtained from NASA's Infrared Telescope Facility on Mauna Kea, Hawaii, except for the 2011 image in the 8.7-micron wavelength (right column, third from the top), which was taken by the Subaru Telescope, also in Mauna Kea, Hawaii. Those data showed a thickening of the deeper cloud decks in the northern belt during that time, and a partial thickening of the upper cloud deck. The South Equatorial Belt saw both levels of clouds thicken and then clear up. The infrared data also resolved brown elongated features in the whitened area of the North Equatorial Belt known as "brown barges" as distinct features and revealed them to be regions clearer of clouds and probably characterized by downwelling, dry air."[3]
"Also visible in the infrared observations are a series of blue-gray features that are the clearest and driest regions on the planet and show up as apparent hotspots in the infrared view because they reveal the radiation emerging from a very deep layer of Jupiter's atmosphere. Those hotspots disappeared from 2010 to 2011, but had reestablished themselves by June of this year, coincident with the whitening and re-darkening of the North Equatorial Belt."[3]
References
- ↑ Damian Peach (23 December 2015). Once Around The Sun With Jupiter. Universe Today. http://www.universetoday.com/121259/once-around-the-sun-with-jupiter/. Retrieved 2017-02-12.
- ↑ 2.0 2.1 2.2 2.3 Bob King (23 December 2015). Once Around The Sun With Jupiter. Universe Today. http://www.universetoday.com/121259/once-around-the-sun-with-jupiter/. Retrieved 2017-02-12.
- ↑ 3.0 3.1 3.2 A. Wesley, A. Kazemoto and C. Go (March 2012). Global Upheaval at Jupiter. SWRI. https://www.missionjuno.swri.edu/media-gallery/jupiter. Retrieved 2017-02-12.
Thor
Thor is associated with the planet Jupiter in Germanic paganism (Germanic mythology).[1]
In Norse mythology, largely recorded in Iceland from traditional material stemming from Scandinavia, numerous tales and information about Thor are provided. In these sources, Thor bears at least fifteen names, is the husband of the golden-haired goddess Sif, is the lover of the jötunn Járnsaxa, and is generally described as fierce eyed, red haired and red bearded.[2] With Sif, Thor fathered the goddess (and possible Valkyrie) Þrúðr; with Járnsaxa, he fathered Móði and Magni (Magni); with a mother whose name is not recorded, he fathered Móði and Magni (Móði), and he is the stepfather of the god Ullr. By way of Odin, Thor has numerous brothers, including Baldr. Thor has two servants, Þjálfi and Röskva Þjálfi and Röskva, rides in a cart or chariot pulled by two goats, Tanngrisnir and Tanngnjóstr Tanngrisn and Tanngnjóstr]] (that he eats and resurrects), and is ascribed three dwellings (Bilskirnir, Þrúðheimr, and Þrúðvangr). Thor wields the mountain-crushing hammer, Mjölnir, wears the belt Megingjörð and the iron gloves Járngreipr], and owns the staff Gríðarvölr. Thor's exploits, including his relentless slaughter of his foes and fierce battles with the monstrous serpent Jörmungandr—and their foretold mutual deaths during the events of Ragnaröko—are recorded throughout sources for Norse mythology.
Old Norse Þórr, Old English ðunor, Old High German Donar, Old Saxon thunar, and Old Frisian thuner are cognates within the Germanic language branch, descending from the Proto-Germanic masculine noun *þunraz 'thunder'.[3]
References
- ↑ Falk, Michael (1999). "Astronomical Names for the Days of the Week". Journal of the Royal Astronomical Society of Canada 93: 122–33. doi:10.1016/j.newast.2003.07.002.
- ↑ On the red beard and the use of "Redbeard" as an epithet for Thor, see Hilda Ellis Davidson (H.R. Ellis Davidson), Gods and Myths of Northern Europe, 1964, repr. Harmondsworth, Middlesex: Penguin, 1990, ISBN 0-14-013627-4, p. 85, citing the Óláfs saga Tryggvasonar en mesta (Saga of Olaf Tryggvason) in Flateyjarbók, Saga of Erik the Red, and Flóamanna saga. The Prologue to the Prose Edda says ambiguously that "His hair is more beautiful than gold."
- ↑ Orel, Vladimir (2003). A Handbook of Germanic Etymology. Brill Publishers. ISBN 9004128751.
External links
Jupiter appears in pastel colors in this photo because the observation was taken in near-infrared light. Credit: NASA, ESA, and E. Karkoschka (University of Arizona).
Rings
"This mosaic of Jupiter's ring system was acquired by NASA's Galileo spacecraft when the Sun was behind the planet, and the spacecraft was in Jupiter's shadow peering back toward the Sun."[1]
"In such a configuration, very small dust-sized particles are accentuated so both the ring particles and the smallest particles in the upper atmosphere of Jupiter are highlighted. Such small particles are believed to have human-scale lifetimes, i.e., very brief compared to the solar system's age."[1]
"Jupiter's ring system is composed of three parts: a flat main ring, a toroidal halo interior to the main ring, and the gossamer ring, which lies exterior to the main ring. Only the main ring and a hint of the surrounding halo can be seen in this mosaic. In order to see the less dense components (the outer halo and gossamer ring) the images must be overexposed with respect to the main ring."[1]
"This composite of two mosaics was taken through the clear filter (610 nanometers) of the solid state imaging (CCD) system on November 9, 1996, during Galileo's third orbit of Jupiter. The ring was approximately 2,300,000 kilometers away. The resolution is approximately 46 kilometers per picture element from right to left; however, because the spacecraft was only about 0.5 degrees above the ring plane, the image is highly foreshortened in the vertical direction. The vertical bright arcs in the middle of the ring mosaics show the edges of Jupiter and are composed of images obtained by NASA's Voyager spacecraft in 1979."[1]
References
- ↑ 1.0 1.1 1.2 1.3 Sue Lavoie (15 September 1998). PIA01621: Jupiter's Ring System. Pasadena, California USA: NASA/JPL. https://photojournal.jpl.nasa.gov/catalog/PIA01621. Retrieved 28 June 2018.
Callisto
Above is a complete global color image of Callisto.
"This fascinating region [in the image at the right] of Jupiter's icy moon, Callisto, shows the transition from the inner part of an enormous impact basin, Asgard, to the outer "surrounding plains." Small, bright, fine textured, closely spaced bumps appear throughout the inner part of the basin (top of image) and create a more fine textured appearance than that seen on many of the other inter-crater plains on Callisto. At low resolution, these icy bumps make Asgard's center brighter than the surrounding terrain. What caused the bumps to form is still unknown, but they are associated clearly with the impact that formed Asgard."[1]
"The ridge that cuts diagonally across the lower left corner is one of many giant concentric rings that extend for hundreds of kilometers outside Asgard's center. Exterior to the ring (lower left corner), Callisto's surface changes significantly. Still peppered with craters, the number of icy bumps decreases while their average size increases. The fine texture is not as visible in the middle of the image. One explanation is that material from raised features (such as the ridge) may slide down slope and cover small scale features. Such images of Callisto help us understand the dynamics of giant impacts into icy surfaces, and how the large structures change with time."[1]
"North is to the top of the picture. The image, centered at 27.1 degrees north latitude and 142.3 degrees west longitude, covers an area approximately 80 kilometers (50 miles) by 90 kilometers (55 miles). The resolution is about 90 meters (295 feet) per picture element. The image was taken on September 17th, 1997 at a range of 9200 kilometers (5700 miles) by the Solid State Imaging (SSI) system on NASA's Galileo spacecraft during its tenth orbit of Jupiter."[1]
References
- ↑ 1.0 1.1 1.2 Sue Lavoie (October 13, 1998). PIA01629: Textured Terrain in Callisto's Asgard Basin. Pasadena, California USA: NASA/JPL. http://photojournal.jpl.nasa.gov/catalog/PIA01629. Retrieved 2014-06-24.
Coronal clouds
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.
"Favorable oppositions occur when Jupiter is passing through perihelion, an event that occurs once per orbit. As Jupiter approached perihelion in March 2011, there was a favorable opposition in September 2010.[1]
It's orbital period is 4,332.59 d (11.8618 y).
"It is shown that starting with the alignment of Venus with Jupiter at perihelion position, these two planets will perfectly align at Jupiter's perihelion after every 23.7 years".[2]
"The tidal forces hypothesis for solar cycles has been proposed by Wood (1972) and others. Table 2 below shows the relative tidal forces of the planets on the sun. Jupiter, Venus, Earth and Mercury are called the "tidal planets" because they are the most significant. According to Wood, the especially good alignments of J-V-E with the sun which occur about every 11 years are the cause of the sunspot cycle. He has shown that the sunspot cycle is synchronous with the alignments, and J. Schove's data for 1500 year of sunspot maxima supports the 11.07 year J-V-E period average."[3]
"Both the 11.86 year Jupiter tropical period (time between perihelion's or closest approaches to the sun and the 9.93 year J-S alignment periods are found in sunspot spectral analysis. Unfortunately direct calculations of the tidal forces of all planets does not support the occurrence of the dominant 11.07 year cycle. Instead, the 11.86 year period of Jupiter's perihelion dominates the results. This has caused problems for several researchers in this field."[3]
The coronal cloud around Jupiter is exactly opposite to that around the Sun. At the Sun there are polar coronal holes, whereas at Jupiter the coronal cloud is most prevalent over the magnetic poles.
References
- ↑ Horizons output. Favorable Appearances by Jupiter. http://home.surewest.net/kheider/astro/jup2010.txt. Retrieved 2008-01-02. (Horizons)
- ↑ S.D. Verma (1986). K. B. Bhatnagar. ed. Influence of Planetary Motion and Radial Alignment of Planets on Sun, In: Space Dynamics and Celestial Mechanics. 127. Springer Netherlands. pp. 143-54. doi:10.1007/978-94-009-4732-0_13. ISBN 978-94-010-8603-5. http://link.springer.com/chapter/10.1007/978-94-009-4732-0_13. Retrieved 2013-07-07.
- ↑ 3.0 3.1 Ray Tomes (February 1990). Towards a Unified Theory of Cycles. Cycles Research Institute. pp. 21. http://cyclesresearchinstitute.org/cycles-general/tomes_unified_cycles.pdf. Retrieved 2013-07-07.