Scientists See Supernova in Action

Scientists See Supernova in Action

Supernova 2007uy in the galaxy NGC2770 was already several weeks old on January 7, 2008 when NASA's Swift satellite took the image at left.
The image on the right was taken two days later and shows Supernova 2008D as well.

Astronomers witnessing the birth of an exploding star for the first time have seen a burst of X-rays as the star disintegrates.
Image: Supernova SN2008D.


A star trembled on the brink of eternity.
Outwardly all was serene, but its inside was falling into chaos.

Far away on the day of Jan. 9, Earth time, a satellite telescope by the name of Swift, which happened to be gazing at the star”s galaxy, a smudge of stars 88 million light-years away in the constellation Lynx, recorded an unexpected burst of invisible X-rays 100 billion times as bright as the Sun.

Alicia Soderberg, a Princeton astronomer who had been using the NASA satellite to study the fading remains of a previous supernova explosion, received the startling results of that observation by e-mail while giving a talk in Michigan.
Recognizing that this was something extraordinary, she sounded a worldwide alert.

In the following hours and days, as most of the big telescopes on Earth, and the Hubble Space Telescope and the Chandra X-ray Observatory watched from space, the star erupted into cataclysmic explosion known as a supernova, lighting up its galaxy and delighting astronomers who had never been able to catch an exploding star before it exploded.

“We caught the whole thing on tape, so to speak,” Dr. Soderberg said in an interview.
“I truly won the astronomy lottery. A star in the galaxy exploded right in front of my eyes.”

She and 42 colleagues from around the world have now told the tale of this discovery in a paper in Nature to be published Thursday and in a telephone news conference Wednesday.
The observations, they say, provide a new window into the process by which the most massive stars end their lives and give astronomers new clues on how to look for these rare events and catch them while they are still in their most explosive, formative stages.

”Most supernovas,” Dr. Soderberg explained, “are discovered and classified by their visible light, but that typically does not happen until theexplosion is a month or more old and has brightened enough to be seen over intergalactic distances.”

The true fireworks, she said, happen much earlier when a shock wave from the imploding core hits the star’s surface, producing so-called breakout light, which lasts only a few minutes.

“The physics of the explosion is encoded in the breakout light,” Dr. Soderberg said, adding that the chance that the Swift telescope was observing during those moments was “unfathomable.”
Astronomers now know, however, that X-rays from the breakout can be an early alert. “Supernova 2008D was the first to be found from its X-ray emission,” said Robert Kirshner, a supernova expert at the Harvard-Smithsonian Center for Astrophysics, referring to the supernova by its official name, “but if we build the right type of X-ray satellites, it won”t be the last supernova we find this way.”

“That is really what is so wonderful here,” he said.

”So new were the X-rays,” said Dr. Soderberg, “that she and her collaborators did not know they were looking at an incipient supernova until a day or two later and ground-based telescopes had seen it grow in visible light.”

“It was a baby supernova in that sense,” Dr. Soderberg said.
“Here was an object brand new. At first we didn”t recognize it.”

The supernova was of a sort known as Type Ibc, the rarest and most luminous of the explosions caused by the collapse of the cores of massive stars, theastronomers have concluded.
Another kind, known as Type Ia supernovas, are believed to result from the destruction of much smaller stars and are beloved of cosmologists who use them to track the expansion of the universe and effects of dark energy.

The star that died last January could have been 20 times as massive as the Sun or even bigger, Dr. Soderberg said.
It was probably a type called a Wolf-Rayet star.
They are very hot stars with surface temperatures of 50,000 degrees Fahrenheit or more and are often blowing gas away in strong winds. Dr. Soderberg described them as “very violent stars, very massive.”

Because it is gravity that stokes the thermonuclear furnace at the centers of stars, the more massive they are, the younger they die.
In the case of a star 10 or 20 times as massive as the Sun, it could be only a few million years. “These stars live fast and die young.
We don”t know if they leave a beautiful corpse,” Dr. Kirshner said.

Many of the elements necessary for life and its accessories, like carbon, oxygen, iron and gold, are produced in a thermonuclear frenzy during the final stages of these explosions, which then fling them into space to be incorporated into new stars, new planets, new creatures.

“If you”re wearing gold jewelry,” Dr. Kirshner said, “it came from a supernova explosion.”

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Astronomers observe new red spot on Jupiter

Astronomers observe new red spot on Jupiter

A Hubble close-up of the three red ovals in an undated image. Jupiter has a new freckle -- a third red spot much smaller than the well-known Great Red Spot and a newer one dubbed Red Spot Jr., scientists said on Thursday.

Maggie Fox, Reuters
Published: Thursday, May 22

WASHINGTON :-
Jupiter has a new freckle -- a third red spot much smaller than the well-known Great Red Spot and a newer one dubbed Red Spot Jr., scientists said on Thursday.

The new spot arose from a white oval-shaped storm, and its change to a red color indicates that the storm is swirling up high into the Jovian atmosphere, the international team of planetary scientists said.

The images, taken by the orbiting Hubble space telescope and the Keck telescope in Hawaii, may support the idea that climate change is under way onJupiter, the largest planet in the solar system.
Amateur planet-gazer Christopher Go of Cebu in the Philippines helped locate the new development.

The gas giant's temperatures may be changing by 27 to 36 degrees Celsius, perhaps driving more turbulent storms.

While the Great Red Spot has been visible for as long as 350 years, Red Spot Jr. had only been around since 2006.
The team at the University of California Berkeley said all three spots represent storms and must be towering above the methane in Jupiter's atmosphere.

"If this spot and the Great Red Spot continue on their courses, they will encounter each other in August, and the small oval will either be absorbed or repelled from the Great Red Spot," Michael Wong of Berkeley, who worked on the study, said in a statement.

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The Hubble Photos...Amazing

After correcting an initial problem with the lens, when the Hubble Space Telescope was first launched in 1990, the floating astro-observatory began to relay back to Earth, incredible snapshots of the 'final frontier' it was perusing.

Recently, astronauts voted on the top photographs taken by Hubble, in its 16-year journey so far.Remarking in the article from the Daily Mail, reporter Michael Hanlon says the photos 'illustrate that our universe is not only deeply strange, but also almost impossibly beautiful.'

Hubble telescope's top ten greatest space photographs


The Sombrero Galaxy - 28 million light years from Earth - was voted best picture taken by the Hubble telescope. The dimensions of the galaxy, officially called M104, are as spectacular as its appearance. It has 800 billion suns and is 50,000 light years across.


The Ant Nebula, a cloud of dust and gas whose technical name is Mz3, resembles an ant when observed using ground-based telescopes. The nebula lies within our galaxy between 3,000 and 6,000light years from Earth.


In third place is Nebula NGC 2392, called Eskimo because it looks like a face surrounded by a furry hood. The hood is, in fact, a ring of comet-shaped objects flying away from a dying star. Eskimo is 5,000light years from Earth.


At four is the Cat's Eye Nebula


The Hourglass Nebula, 8,000 light years away, has a pinched-in-the- middle
look because the winds that shape it are weaker at the centre.

In sixth place is the Cone Nebula. The part pictured here is 2.5 light years in
length (the equivalent of 23 million return trips to the Moon).


The Perfect Storm, a small region in the Swan Nebula, 5,500 light years away,
described as 'a bubbly ocean of hydrogen and small amounts of oxygen, sulphur and other elements'.


Starry Night, so named because it reminded astronomers of the Van Gogh painting. It is a halo of light around a star in the Milky Way.


The glowering eyes from 114 million light years away are the swirling cores of two merging galaxies called NGC 2207 and IC 2163 in the distant Canis Major constellation.


The Trifid Nebula. A 'stellar nursery', 9,000 light years from here, it is where new stars are being born.

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Milky Way Loses Two Arms

New infrared images of the Milky Way show just two major spiral arms, Scutum-Centaus and Perseus, along with a newly discovered arm called Far 3kpc Arm.


ST. LOUIS :

For decades, astronomers have pictured our galaxy as sporting four major, spiral arms, however new images effectively sever two appendages, revealing the Milky Way has just two major arms.

"We're not proposing that they change the positions of the arms," said Robert Benjamin of the University of Wisconsin, Whitewater.
"What we're proposing is a change in the emphasis of the arms."
Benjamin will present his team's results today here at a meeting of the American Astronomical Society (AAS).

The results are among a handful of presentations at the meeting to paint an evolving picture of our galactic home base.

For instance, other results presented here by Thomas Dame of the Harvard-Smithsonian Center for Astrophysics (CfA) this week suggest a completely new arm of stars wraps around one side of the galactic center.
This new arm is a virtual twin of a known arm on the near side of the galactic center.
And another group led by Mark Reid of CfA has identified with more accuracy the location and relative distances of the stars within the spiral arms.


Spotlight on a galaxy

The Milky Way debuted as a spiral celebrity in 1951 when astronomical morphologist William Morgan of the Yerkes Observatory presented his results showing the galaxy's three arms of hot stars, which he were then namedPerseus, Orion and Sagittarius.

"Those were the first three arms of the spiral galaxy," Benjamin told SPACE.com.
"Actually, he got a standing ovation at the AAS meeting, which is something I've never seen."

Beginning in the 1960s and through the 1980s, several groups of scientists used radio astronomy to map out the Milky Way's structure, coming up with various results on how the spiral arms looked and the number of arms.

"For years, people created maps of the whole galaxy based on studying just one section of it, or using only one method," Benjamin said.
"Unfortunately, when the models from various groups were compared, they didn't always agree.
It's a bit like studying an elephant blind-folded."

The galactic image that stuck, Benjamin said, was one with the four spiral arms, now called Norma, Scutum-Centaurus, Sagittarius and Perseus.
Our sun lies near a small, partial arm called the Orion Arm, or Orion Spur, located between the Sagittarius and Perseus arms.


Spiral structure

The new survey of an extensive swath of the Milky Way was done with NASA's Spitzer Space Telescope, which detects infrared light.
All objects that emit any heat can be seen in infrared, and this wavelength penetrates dust, so the new mosaic includes 800,000 snapshots and more than 110 million stars.

Using a star-counting method, Benjamin and his colleagues noticed an increase in the number of stars in the direction of the Scutum-Centaurus Arm, but not in the direction of the Sagittarius and Norma arms.
(The fourth arm, Perseus, wraps around the outer portion of our galaxy and cannot be seen in the new Spitzer images.)
The two major arms, according to these findings, are the Scutum-Centaurus and Perseus arms.

The findings confirm an earlier observation by a team of astronomers, making a strong case that the Milky Way has two major spiral arms, a common structure for galaxies with bars.
These major arms have the greatest densities of both young, bright stars and older, so-called red-giant stars.

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Phoenix Mars Lander

Phoenix Mars Lander

Mars is a cold desert planet with no liquid water on its surface. But in the Martian arctic, water ice lurks just below ground level. Discoveries made by the Mars Odyssey Orbiter in 2002 show large amounts of subsurface water ice in the northern arctic plain. The Phoenix lander targets this circumpolar region using a robotic arm to dig through the protective top soil layer to the water ice below and ultimately, to bring both soil and water ice to the lander platform for sophisticated scientific analysis.

(This artist's animation shows NASA's Phoenix Mars Lander taking a picture of its solar panel with its Surface Stereo Imager. The photographed area is highlighted. )

Objectives:

--Determine whether Life ever arose on Mars

--Characterize the Climate of Mars

--Characterize the Geology of Mars

--Prepare for Human Exploration

Study the History of Water in All its Phases

Currently, water on Mars' surface and atmosphere exists in two states: gas and solid. At the poles, the interaction between the solid water ice at and just below the surface and the gaseous water vapor in the atmosphere is believed to be critical to the weather and climate of Mars. Phoenix will be the first mission to collect meteorological data in the Martian arctic needed by scientists to accurately model Mars' past climate and predict future weather processes.

Liquid water does not currently exist on the surface of Mars, but evidence from Mars Global Surveyor, Odyssey and Exploration Rover missions suggest that water once flowed in canyons and persisted in shallow lakes billions of years ago. However, Phoenix will probe the history of liquid water that may have existed in the arctic as recently as 100,000 years ago. Scientists will better understand the history of the Martian arctic after analyzing the chemistry and mineralogy of the soil and ice using robust instruments.

Latest Images by NASA

NASA's Phoenix Mars Lander did a small amount of excavation as it touched down on pebbly north polar terrain on the Red Planet, as shown in this close-up view of one of the lander's three footpads.

This image shows a polygonal pattern in the ground near NASA's Phoenix Mars Lander, similar in appearance to icy ground in the arctic regions of Earth.

This image, one of the first captured by NASA's Phoenix Mars Lander, shows the vast plains of the northern polar region of Mars. The flat landscape is strewn with tiny pebbles and shows polygonal cracking, a pattern seen widely in Martian high latitudes and also observed in permafrost terrains on Earth. The polygonal cracking is believed to have resulted from seasonal freezing and thawing of surface ice.

Historical Log!


Launch Date-Name-Country-Result-Reason
1960-Korabl 4-USSR (flyby)-Failure-Didn't reach Earth orbit

1960-Korabl 5-USSR (flyby)-Failure-Didn't reach Earth orbit

1962-Korabl 11-USSR (flyby)-Failure-Earth orbit only; spacecraft broke apart

1962-Mars 1-USSR (flyby)-Failure-Radio Failed

1962-Korabl 13-USSR (flyby)-Failure-Earth orbit only; spacecraft broke apart

1964-Mariner 3-US (flyby)-Failure-Shroud failed to jettison

1964-Mariner 4-US (flyby)-Success-Returned 21 images

1964-Zond 2-USSR (flyby)-Failure-Radio failed

1969-Mars 1969A-USSR-Failure-Launch vehicle failure

1969-Mars 1969B-USSR-Failure-Launch vehicle failure

1969-Mariner 6-US (flyby)-Success-Returned 75 images

1969-Mariner 7-US (flyby)-Success-Returned 126 images

1971-Mariner 8-US-Failure-Launch failure

1971-Kosmos 419-USSR-Failure-Achieved Earth orbit only

1971-Mars 2 Orbiter/Lander-USSR-Failure-Orbiter arrived, but no useful data and Lander destroyed

1971-Mars 3 Orbiter/Lander-USSR-Success-Orbiter obtained approximately 8 months of data and lander landed safely, but only 20 seconds of data

1971-Mariner 9-US-Success-Returned 7,329 images

1973-Mars 4-USSR-Failure-Flew past Mars

1973-Mars 5-USSR-Success-Returned 60 images; only lasted 9 days

1973-Mars 6 Orbiter/Lander-USSR-Success/Failure-Occultation experiment produced data and Lander failure on descent

1973-Mars 7 Lander-USSR-Failure-Missed planet; now in solar orbit.

1975-Viking 1 Orbiter/Lander-US-Success-Located landing site for Lander and first successful landing on Mars

Historical Log (Cont.)


Launch Date-Name-Country-Result-Reason
1975-Viking 2 Orbiter/Lander-US-Success-Returned 16,000 images and extensive atmospheric data and soil experiments

1988-Phobos 1 Orbiter-USSR-Failure-Lost en route to Mars

1988-Phobos 2 Orbiter/Lander-USSR-Failure-Lost near Phobos

1992-Mars Observer-US-Failure-Lost prior to Mars arrival

1996-Mars Global Surveyor-US-Success-More images than all Mars Missions

1996-Mars 96-USSR-Failure-Launch vehicle failure

1996-Mars Pathfinder-US-Success-Technology experiment lasting 5 times longer than warranty

1998-Nozomi-Japan-Failure-No orbit insertion; fuel problems

1998-Mars Climate Orbiter-US-Failure-Lost on arrival

1999-Mars Polar Lander-US-Failure-Lost on arrival

1999-Deep Space 2 Probes (2)-US-Failure-Lost on arrival (carried on Mars Polar Lander)

2001-Mars Odyssey-US-Success-High resolution images of Mars

2003-Mars Express Orbiter/Beagle 2 Lander-ESA-Success/Failure-Orbiter imaging Mars in detail and lander lost on arrival

2003-Mars Exploration Rover - Spirit-US-Success-Operating lifetime of more than 15 times original warranty

2003-Mars Exploration Rover - Opportunity-US-Success-Operating lifetime of more than 15 times original warranty

2005-Mars Reconnaissance Orbiter-US-Success-Returned more than 26 terabits of data (more than all other Mars missions combined)

2007-Phoenix Mars Lander-US-TBD-

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Astronomy Picture Discover the cosmos!

Discover the cosmos! photograph of our fascinating universe is featured, along with a brief explanation



Hoag's Object: A Strange Ring Galaxy

Is this one galaxy or two? This question came to light in 1950 when astronomer Art Hoag chanced upon this unusual extragalactic object. On the outside is a ring dominated by bright blue stars, while near the center lies a ball of much redder stars that are likely much older. Between the two is a gap that appears almost completely dark. How Hoag'sObject formed remains unknown, although similar objects have now been identified and collectively labeled as a form of ring galaxy. Genesis hypotheses include a galaxy collision billions of years ago and perturbative gravitational interactions involving an unusually shaped core. The above photo taken by the Hubble Space Telescope in July 2001 reveals unprecedented details of Hoag's Object and may yield a better understanding. Hoag's Object spans about 100,000 light years and lies about 600 million light years away toward the constellation of Serpens. Coincidentally, visible in the gap (at about one o'clock) is yet another ring galaxy that likely lies far in the distance.



Venus Beyond the Storm

A thunderstorm, lightning, a bright star and a bright planet all graced an evening sky for a short while near Bismarck, North Dakota, USA two weeks ago. Thick thunderclouds from a passing storm are the origin of a strong cloud to ground lightning strike. Small areas of rain darken portions of the orange sunset, visible at the horizon above the vast prairie. The planet Venus peeks below the clouds on the lower left of the image. Blue sky shines high above the distant storm, streaked with high white cirrus clouds. The bright star Arcturus glitters near the image top, just left of center. Just a few minutes later, only a memory and this picture remained




Pluto & Charon Eclipse a Triple Star

Explanation

Occasionally, a planet in our Solar System will pass in front of a bright star. Since stars and planets take up so little space on the sky, such events are quite rare. Two months ago, however, Pluto and its large moon Charon passed in front of a comparativelybright triple star system known as P126. By noting how P126 A dimmed, the event was useful for studying Pluto's relatively unknown atmosphere. A Very Large Telescope in Chile using a deformable mirror to counter the blurring effect of Earth's atmosphere captured the above image.



X-Rays From Tycho's Supernova Remnant


In 1572, Danish astronomer Tycho Brahe recorded the sudden appearance of a bright new star in the constellation Cassiopeia. The new star faded from view over a period of months and is believed to have been a supernova, one of the last stellar explosions seen in our Milky Way galaxy. Now known as Tycho's Supernova Remnant, the expanding debris cloud is shown in this detailed false-color x-ray image from the orbiting Chandra Observatory. Represented in blue, the highest energy x-rays come from shocked regions along the outer edges of the supernova remnant, corresponding to gas at temperatures of 20 million degrees Celsius. X-rays from cooler gas (only 10 million degrees or so!) dominate the remnant's interior. Unlike some other supernova remnants, no hot central point source can be found, supporting the theory that the origin of this stellar explosion was a runaway nuclear detonation that ultimately destroyed a white dwarf star. At a distance of about 7,500 light-years, Tycho's Supernova Remnant appears to be nearly 20 light-years across. This x-ray picture's field of view slightly cuts off the bottom of the generally spherical cloud



Aristarchus Plateau

Explanation
Anchored in the vast lava flows of the Moon's Oceanus Procellarum lies the Aristarchus Plateau. Recorded from a backyard observatory on planet Earth, this sharp, amazingly colorful view nicely captures the geologically diverse area, including the brownish plateau, Aristarchus and Herodotus craters, and the meandering Vallis Schroteri. Thebright impact crater at the corner of the plateau is Aristarchus, a young crater 42 kilometers wide and 3 kilometers deep, surrounded by a radial system of light-colored rays. Only slightly smaller, lava flooded Herodotus crater is above and to the left. A valley or rille feature likely carved by rapidly flowing lava or a collapsed lava tunnel, Vallis Schroteri begins just to the right of Herodotus and winds across the plateau for about 160 kilometers, eventually turning toward the top of the picture and the shadow of the lunar terminator. Aristarchus Plateau itself is like a rectangular island about 200 kilometers across, raised up to 2 kilometers or so above the smooth surface of the lunar Ocean of Storms

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Glimpses of a rare celestial event..solar Ecplise

The next solar eclipse -- a partial one -- will occur on January 26 next year but the phenomenon will be marginally visible from eastern and southernIndia.





India will witness a partial eclipse of the Sun beginning in the northeast of India on Friday.
It will begin at 4:03 pm in Delhi. It will last for about two hours with maximum impact at 5.02 pm. In the rest of the country, the partial eclipse will be visible a few minutes later.

However, some parts of the world will witness a rare total solar eclipse -- when the moon will pass directly between the earth and the sun.


The eclipse will begin in Arctic Canada and sweep across Greenland, western Siberia, Mongolia and central China.

Viewers all across the globe can see the eclipse as it happens on NASA TV and by logging on to www.nasa.gov. The US space agency has made arrangements to telecast live images of the rare celestial event.




Image: Indians will miss this sight -- A total solar eclipse



August 01, 2008

According to Nehru Planetarium director Rathnasree, the maximum obscuration of the sun will occur at Sibsagar in Assam..
The biggest and last phase of the eclipse will be visible from most parts of the country, except Nagaland and Mizoram, where it ends after sunset, she said.

The southern parts of India will see between 20 to 40 per cent of the sun's diameter while the northern parts of the country will see between 40 to 70 per cent of the sun's diameter.




Image: A combo photograph of the partial solar eclipse.

August 01, 2008

People must also avoid watching the eclipse through sunglasses, single or multiple layers, smoked glass, colour film or black-and-white film that contains no silver or photographic negatives with images on them.
The Nehru Planetarium, in collaboration with the Amateur Astronomers Association, Delhi will be conducting public sky-watch for the eclipse from the Jantar Mantar, the planetarium and the India Gate area.




Image: A multiple exposure photograph shows the progress of a total solar eclipse. The sequence begins at the upper left.

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Some Bizarre Things in Space

From miniature black holes to distortions in the fabric of space-time, from galaxies that are eating each other to matter that can neither be seen nor detected directly…space is full of many strange things. And here are some of the strangest.

1. Neutrinos



Neutrinos are electrically neutral, virtually mass-less elementary particles that can pass through miles of lead unhindered. Some are passing through your body as you read this. These “phantom” particles are produced in the inner fires of burning, healthy stars as well as in the supernova explosions of dying stars. Detectors are being embedded underground, beneath the sea, or into a large chunk of ice as part of IceCube, a neutrino-detecting project.

2. Galactic Cannibalism



Like life on Earth, galaxies can “eat” each other and evolve over time. The Milky Way’s neighbor, Andromeda, is currently dining on one of its satellites. More than a dozen star clusters are scattered throughout Andromeda, the cosmic remains of past meals. The image above is from a simulation of Andromeda and our galaxy colliding, an event that will take place in about 3 billion years.

3. Gravity Waves


Gravity waves are distortions in the fabric of space-time predicted by Albert Einstein’s theory of general relativity. The waves travel at the speed of light, but they are so weak that scientists expect to detect only those created during colossal cosmic events, such as black hole mergers like the one shown above. LIGO and LISA are twodetectors designed to spot the elusive waves.

4. Exoplanets



Until about the early 1990s, the only known planets in the universe were the familiar ones in our solar system. Astronomers have since identified more than 190 extrasolar planets (as of June 2006). They range from gargantuan gas worlds whose masses are just shy of being stars to small, rocky ones orbiting dim, red dwarfs. Searches for a second Earth, however, have so far turned up empty. Astronomers generally believe that better technology is likely to eventually reveal several worlds similar to our own.

5. Dark Matter



Scientists think it makes up the bulk of matter in the universe, but it can neither be seen nor detected directly using current technologies. Candidates range from light-weight neutrinos to invisible black holes. Some scientists question whether dark matter is even real, and suggest that the mysteries it was conjured to solve could be explained by a better understanding of gravity.

6. Cosmic Microwave Background


Also known as the CMB, this radiation is a primordial leftover from the Big Bang that birthed the universe. It was first detected during the 1960s as a radio noise that seemed to emanate from everywhere in space. The CMB is regarded as one of the best pieces of evidence for the theoretical Big Bang. Recent precise measurements by the WMAP project place the CMB temperature at -455 degrees Fahrenheit (-270 Celsius).

]7. Mini Black Holes


If a radical new “braneworld” theory of gravity is correct, then scattered throughout our solar system are thousands of tiny black holes, each about the size of an atomic nucleus. Unlike their larger brethren, these mini-black holes are primordial leftovers from the Big Bang and affect space-time differently because of their close association with a fifth dimension.



8. Anti-matter

Like Superman’s alter-ego, Bizzaro, the particles making up normal matter also have opposite versions of themselves. An electron has a negative charge, for example, but its anti-matter equivalent, the positron, is positive. Matter and anti-matter annihilate each other when they collide and their mass is converted into pure energy by Einstein’s equation E=mc2. Some futuristic spacecraft designs incorporate anti-matter engines.

9. Vacuum Energy


Quantum physics tells us that contrary to appearances, empty space is a bubbling brew of “virtual” subatomic particles that are constantly being created and destroyed. The fleeting particles endow every cubic centimeter of space with a certain energy that, according to general relativity, produces an anti-gravitational force that pushes space apart. Nobody knows what’s really causing the accelerated expansion of the universe, however.

10. Quasars


These bright beacons shine to us from the edges of the visible universe and are reminders to scientists of our universe’s chaotic infancy. Quasars release more energy than hundreds of galaxies combined. The general consensus is that they are monstrous black holes in the hearts of distant galaxies. This image is of quasar 3C 273, photographed in 1979

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Amazing Views of Jupiter

Jupiter's moon Io floats above the cloudtops of Jupiter in this image captured January 1, 2001. The image is deceiving: there are 350,000 kilometers - roughly 2.5 Jupiters - between Io and Jupiter's clouds. Io is about the size of our own moon


Jupiter is in the news again, this time because its "Baby Red Spot" - a storm less than a year old - appears to have been swallowed up by the massive storm known as the Great Red Spot. This is good occasion to share some of the best photographs of Jupiter and its larger system of rings and moons, as seen by various probes and telescopes over the past 30 years





This image of Jupiter's moon Europa rising above Jupiter was captured by the New Horizons spacecraft in February just after it passed Jupiter on its way to Pluto and the outer Solar System.

The gibbous phase of Jupiter's moon Europa. The robot spacecraft Galileo captured this image mosaic during its mission orbiting Jupiter from 1995 - 2003. Evidence and images from the Galileo spacecraft, indicated that liquid oceans might exist below the icy surface.





This view of the icy surface of Jupiter's moon, Europa, is a mosaic of two pictures taken by the Solid State Imaging system on board the Galileo spacecraft during a close flyby of Europa on February 20, 1997. The area shown is about 14 kilometers by 17 kilometers (8.7 miles by 10.6 miles), and has a resolution of 20 meters (22 yards) per pixel. One of the youngest features seen in this area is the double ridge cutting across the picture from the lower left to the upper right. This double ridge is about 2.6kilometers (1.6 miles) wide and stands some 300 meters (330 yards) high.

A composite of several images taken in several colors by the New Horizons Multispectral Visual Imaging Camera, or MVIC, illustrating the diversity of structures in Jupiter's atmosphere, in colors similar to what someone "riding" on New Horizons would see. It was taken near the terminator, the boundary between day and night, and shows relatively small-scale, turbulent, whirlpool-like structures near the south pole of the planet. The dark "holes" in this region are actually places where there is very little cloud cover, so sunlight is not reflected back to the camera.






This image, acquired during Galileo's ninth orbit around Jupiter, shows two volcanic plumes on Io. One plume was captured on the bright limb or edge of the moon, erupting over a caldera (volcanic depression) named Pillan Patera. The plume seen by Galileo is 140 kilometers (86 miles) high, and was also detected by the Hubble Space Telescope. The second plume, seen near the terminator, the boundary between day and night, is called Prometheus. The shadow of the airborne plume can be seen extending to the right of the eruption vent.




A part of the southern hemisphere of Io, seen by the spacecraft Voyager at a range of 74,675 km. In the foreground is gently undulating topography, while in the back-ground are two mountains with their near faces brightly illuminated by the sun. The mountain in the right is approximately 150 km across at its base and its height is probably in excess of 15 km which would make it higher than any mountain on Earth.




This five-frame sequence of New Horizons images captures the giant plume from Io's Tvashtar volcano. Snapped by the probe's Long Range Reconnaissance Imager (LORRI) as the spacecraft flew past Jupiter earlier this year, this first-ever "movie" of an Io plume clearly shows motion in the cloud of volcanic debris, which extends 330 kilometers (200 miles) above the moon's surface. Only the upper part of the plume is visible from this vantage point - the plume's source is 130 kilometers (80 miles) below the edge of Io's disk, on the far side of the moon.

A volcanic plume rises over 300 kilometers above the horizon of Jupiter's moon Io in this image from cameras onboard the New Horizons spacecraft. The volcano, Tvashtar, is marked by the bright glow (about 1 o'clock) at the moon's edge, beyond the terminator or night/day shadow line. The shadow of Io cuts across theplume itself. Also capturing stunning details on the dayside surface, the high resolution image was recorded when the spacecraft was 2.3 million kilometers from Io. Later it was combined with lower resolution color data by astro-imager Sean Walker to produce this sharp portrait of the solar system's most active moon.




Jupiter's moon Io, seen by NASA's Galileo spacecraft against a backdrop of Jupiter's cloud tops, which appear blue in this false-color composite.






The first color movie of Jupiter from NASA's Cassini spacecraft shows what it would look like to peel the entire globe of Jupiter, stretch it out on a wall into the form of a rectangular map, and watch its atmosphere evolve with time. The brief movie clip spans 24Jupiter rotations between Oct. 31 and Nov. 9, 2000. The darker blips that appear are several moons and their shadows.





Jupiter's Great Red seen by NASA's Voyager spacecraft. July, 1979 Around the northern boundary a white cloud is seen, which extends to east of the region. The presence of this cloud prevents small cloud vortices from circling the spot in the manner seen in the Voyager 1 encounter. Another white oval cloud (different from the one present in this position three months ago) is seen south of the Great Red Spot. This image was taken on July 6, 1979 from a range of 2,633,003 kilometers. The Red Spot is 20,000 km across.[/I

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