Pictorial Reportage of Various Phenomenon of SUN

 

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An extensive distinction, an enormous cloud of comparatively cool thick plasma is seen hovering on the Sun's hot, thin corona. At times, prominences can erupt, escaping the Sun's atmosphere. Emission in this spectral line shows the upper chromosphere at a temperature of about 60,000 degrees K (over 100,000 degrees F). The hottest areas appear almost white, while the darker red areas indicate cooler temperatures. (Courtesy of SOHO/EIT consortium)  Know More about our SUN

 

Detailed closeup of magnetic structures on the Sun's surface, seen in the H-alpha wavelength on August 22, 2003. (Swedish 1-m Solar Telescope (SST) operated by the Royal Swedish Academy of Sciences, Oddbjorn Engvold, Jun Elin Wiik, Luc Rouppe van der Voort)  Know More about our SUN  

NASA's STEREO satellite captured the first images ever of a collision between a solar "hurricane", called a coronal mass ejection (CME), and a comet on April  4, 2007. The collision caused the complete detachment of the comet's plasma  tail. Comets are icy leftovers from the solar system's formation billions of  years ago. They usually hang out in the cold, distant regions of the solar  system, but occasionally a gravitational tug from a planet, another comet, or  even a nearby star sends them into the inner solar system. Once there, the  sun's heat and radiation vaporizes gas and dust from the comet, forming its  tail. Comets typically have two tails, one made of dust and a fainter one  made of electrically conducting gas, called plasma. (NASA/STEREO) #  Know More about our SUN

 

 Image of an active solar region taken on July 24, 2002 near the eastern limb  of the Sun. The image highlights the three-dimensional nature of the  photosphere when seen at these large angles. The structures in the dark  sunspots in the upper central area of the image show distinct elevation above  the dark "floor" of the sunspot. The height of the structures has been  estimated by Dr. Bruce Lites of the High Altitude Observatory to be between  200 and 450 km. The smallest resolvable features in the image are about 70  km in size. There are also numerous bright "faculae" visible on the edges of  granules that face towards the observer. (Prof. Goran Scharmer/Dr. Mats G.  Löfdahl/Institute for Solar Physics of the Royal Swedish Academy of Sciences) #  Know More about our SUN

 

 The total solar eclipse of February 16, 1980 was photographed from Palem,  India, by a research team from the High Altitude Observatory of the National  Center for Atmospheric Research. The photograph of the solar corona was  taken with a camera system developed by Gordon A. Newkirk, Jr. This  specialized instrument photographs the corona in red light, 6400 A -- through  a radially graded filter that suppresses the bright inner corona in order to  show the much fainter streamers of the outer corona in the same photograph.  (Rhodes College, Memphis, Tennessee / High Altitude Observatory (HAO),  University Corporation for Atmospheric Research (UCAR)) #  Know More about our SUN

 

 The planet Venus is seen by NASA's TRACE satellite, at the start of its transit  across the sun on June 8, 2004. (NASA/TRACE) #  Know More about our SUN

 

 A view of a sunspot and granules on the Sun's surface, seen in the H-alpha  wavelength on August 4, 2003. (Swedish 1-m Solar Telescope (SST) operated  by the Royal Swedish Academy of Sciences, Göran Scharmer and Kai Langhans, ISP) #  Know More about our SUN

 

 Solar flares produce seismic waves in the Sun's interior that closely resemble  those created by earthquakes on our planet. On May 27, 1998, researchers  observed this flare-generated solar quake that contained about 40,000 times  the energy released in the great earthquake that devastated San Francisco in  1906, equivalent to an 11.3 magnitude earthquake, scientists calculated.  Over the course of an hour, the solar waves traveled for a distance equal to  10 Earth diameters before fading into the fiery background of the Sun's  photosphere. Unlike water ripples that travel outward at a constant velocity,  the solar waves accelerated from an initial speed of 22,000 miles per hour to  a maximum of 250,000 miles per hour before disappearing. (Courtesy of  SOHO/EIT consortium. SOHO is a project of international cooperation between  ESA and NASA) #  Know More about our SUN

 

An animation of the sun, seen by NASA's Extreme ultraviolet Imaging  Telescope (EIT) over the course of 6 days, starting June 27, 2005. (Courtesy  of SOHO/EIT consortium) #  Know More about our SUN

 

 Hinode (formerly known as Solar-B) successfully captured a massive solar  flare on 13 December 2006. It was one of the largest flares occurring in that  period of solar activity minimum. (JAXA/NASA/PPARC) #  Know More about our SUN

 

 The image shows the corona for a moderately active Sun, with some (red)  hot active regions in both hemispheres, surrounded by the (blue/green) cooler  plasma of the quiet-Sun corona. Notice also the north polar-crown filament,  the trans-equatorial loops, and the coronal hole in the south-east (lower-right) corner of the image and the smaller one over the north pole. This image  shows the solar corona in a false-color, 3-layer composite: the blue, green,  and red channels show the 171Å, 195Å, and 284Å wavelengths, respectively  (most sensitive to emission from 1, 1.5, and 2 million degree gases). (TRACE  Project, Stanford-Lockheed Institute for Space Research, NASA) #

 

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 A view of an irregular-shaped sunspot and granules on the Sun's surface,  seen on August 22, 2003. (Swedish 1-m Solar Telescope (SST) operated by  the Royal Swedish Academy of Sciences, Oddbjorn Engvold, Jun Elin Wiik, Luc  Rouppe van der Voort, Oslo) #

 

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 On November 8, 2006, Mercury is seen, beginning a transit in front of the  Sun. (NASA/TRACE) #

 

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 This TRACE 171Å-wavelength image from November 11, 2006 shows a sizeable  active region at the east limb of the Sun (rotated clockwise 90 degrees so  north is to the right) just as it rotates onto Earth-facing hemisphere. Notice  the low-lying dark structures of filaments at the leading edge of the region,  some "levitating" dark material on the right-hand side of the region, and the  small ephemeral region towards the lower right. (NASA/TRACE) #  Know More about our SUN

 

 The Sun, observed on May 22, 2008. With the Sun persisting in a  near-minimal state of activity, only a few small regions of some activity are  seen on the disk. The cell-like appearance is formed by the multitude of small  clusters of magnetic flux that are collected in the downflow regions of the  supergranular network of convective motions. (NASA/TRACE) #  Know More about our SUN

 

 A display of thin loops is seen arching above active regions of the Sun on  January 1, 2001. (Courtesy Dick Shine, NASA/TRACE) #  Know More about our SUN

 

 This LASCO C2 image, taken 8 January 2002, shows a widely spreading  coronal mass ejection (CME) as it blasts more than a billion tons of matter out  into space at millions of kilometers per hour. The C2 image was turned 90  degrees so that the blast seems to be pointing down. An EIT 304 Angstrom  image from a different day was enlarged and superimposed on the C2 image  so that it filled the occulting disk for effect (Courtesy of SOHO/LASCO  consortium) #  Know More about our SUN

 

Detailed closeup of magnetic structures on the Sun's surface, seen in the  H-alpha wavelength on August 22, 2003. (Swedish 1-m Solar Telescope (SST)  operated by the Royal Swedish Academy of Sciences, Oddbjorn Engvold, Jun  Elin Wiik, Luc Rouppe van der Voort, Oslo) #

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 NASA's STEREO (Ahead) spacecraft observed this visually stunning  prominence eruption on Sept. 29, 2008 in the 304 wavelength of extreme UV  light. It rose up and cascaded to the right over several hours, appearing  something like a flag unfurling, as it broke apart and headed into space. The  material observed is actually ionized Helium at about 60,000 degrees.  Prominences are relatively cool clouds of gas suspended above the Sun and  controlled by magnetic forces. (NASA/STEREO) #  Know More about our SUN

 

 A transit of the Moon across the face of the Sun on February 25, 2007 - but  not seen from Earth. This sight was visible only from the STEREO-B  spacecraft in its orbit about the sun, trailing behind the Earth. NASA's  STEREO mission consists of two spacecraft launched in October, 2006 to  study solar storms. STEREO-B is currently about 1 million miles from the Earth,  4.4 times farther away from the Moon than we are on Earth. As the result,  the Moon appears 4.4 times smaller than what we are used to. (NASA/STEREO) #

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 On September 30, 2001, TRACE observed an M1.0 flare in an active region  very near to the solar limb. Fragments of a prominence hovered above the  regions, with filamentary dark (relatively cool) material moving along the field  lines, which then spread to form this dragon-like bright outline. (NASA/TRACE)  #