Atlas V rocket blasts off from Space Launch Complex-41

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A United Launch Alliance Atlas V rocket blasts off from Space Launch Complex-41 carrying the second Space-Based Infrared System (SBIRS) GEO-2 satellite for the U.S. Air Force at 5:21 p.m. EDT. This was the 3rd ULA launch of the year, the 37th Atlas V mission, and the 69th ULA launch since the company was formed in December 2006. SBIRS is a consolidated system intended to meet United States infrared space surveillance needs for decades to come. The SBIRS program addresses critical warfighter needs in the areas of missile warning, missile defense, technical intelligence and battlespace characterization. (Photo Credit: Pat Corkery, United Launch Alliance)

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Black Hole : Star Pair Orbiting at dizzying speed

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MAXI J1659­–152
Video By ESA
MAXI J1659­–152

ESA’s XMM-Newton space telescope has helped to identify a star and a black hole that orbit each other at the dizzying rate of once every 2.4 hours, smashing the previous record by nearly an hour.

The black hole in this compact pairing, known as MAXI J1659-152, is at least three times more massive than the Sun, while its red dwarf companion star has a mass only 20% that of the Sun. The pair is separated by roughly a million kilometres.
The duo were discovered on 25 September 2010 by NASA’s Swift space telescope and were initially thought to be a gamma-ray burst. Later that day, Japan’s MAXI telescope on the International Space Station found a bright X-ray source at the same place.
More observations from ground and space telescopes, including XMM-Newton, revealed that the X-rays come from a black hole feeding off material ripped from a tiny companion.
Several regularly-spaced dips in the emission were seen in an uninterrupted 14.5 hour observation with XMM-Newton, caused by the uneven rim of the black hole’s accretion disc briefly obscuring the X-rays as the system rotates, its disc almost edge-on along XMM-Newton’s line of sight.
From these dips, an orbital period of just 2.4 hours was measured, setting a new record for black hole X-ray binary systems. The previous record-holder, Swift J1753.5–0127, has a period of 3.2 hours.
The black hole and the star orbit their common centre of mass. Because the star is the lighter object, it lies further from this point and has to travel around its larger orbit at a breakneck speed of two million kilometres per hour – it is the fastest moving star ever seen in an X-ray binary system. On the other hand, the black hole orbits at ‘only’ 150 000 km/h.
“The companion star revolves around the common centre of mass at a dizzying rate, almost 20 times faster than Earth orbits the Sun. You really wouldn’t like to be on such a merry-go-round in this Galactic fair!” says lead author Erik Kuulkers of ESA’s European Space Astronomy Centre in Spain.
His team also saw that they lie high above the Galactic plane, out of the main disc of our spiral Galaxy, an unusual characteristic shared only by two other black-hole binary systems, including Swift J1753.5–0127.
“These high galactic latitude locations and short orbital periods are signatures of a potential new class of binary system, objects that may have been kicked out of the Galactic plane during the explosive formation of the black hole itself,” says Dr Kuulkers.
Returning to MAXI J1659−152, the quick response of XMM-Newton was key in being able to measure the remarkably short orbital period of the system.
“Observations started at tea-time, just five hours after we received the request to begin taking measurements, and continued until breakfast the next day. Without this rapid response it would not have been possible to discover the fastest rotation yet known for any binary system with a black hole,” adds Norbert Schartel, ESA’s XMM-Newton project scientist.
Source : ESA

NASA- Image of the day

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Clouds Over the Southern Indian Ocean

Marine stratocumulus clouds stretched across the southern Indian Ocean in early March 2013. The Moderate Resolution Imaging Spectroradiometer (MODIS) on NASA’s Aqua satellite acquired this natural-color image on March 11, as a striking band of clouds ran roughly northwest to southeast over the open ocean.
Earth’s boundary layer extends upward from the land or ocean surface to roughly 2 kilometers (1 mile) in altitude, and it is the part of the atmosphere where interactions with the planet surface have the strongest effects. Patrick Minnis of NASA’s Langley Research Center explains that the clouds in this image likely formed underneath a strong inversion, in which air above the boundary layer was sinking. “The clouds in the northwest are below one kilometer in altitude,” Minnis noted, “while the remaining clouds, which are thicker and more developed, are between one and two kilometers.”
Image Credit: NASA

Mangalayaan by ISRO in November

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Science & Universe : Mangalayaan by ISRO
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The Mangalyaan mission (Mars Mission) is a planned Mars orbiter to be launched in November 2013 by the Indian Space Research Organisation (ISRO). The mission is a "technology demonstrator" project aiming to develop the technologies required for design, planning, management and operations of an interplanetary mission.

The Mangalyaan Mars probe will lift off from ISRO's launch site at Sriharikota, Andhra Pradesh, using a Polar Satellite Launch Vehicle (PSLV) rocket; this will be India's first mission to Mars.

A United Launch Alliance Atlas V rolls out for launch

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United Launch Alliance Atlas V rolls out for launch at Space Launch Complex-41 with the Air Force’s Space-Based Infrared System (SBIRS) GEO-2 spacecraft. Launch is set for Tuesday, March 19 at 5:21 p.m. EDT. SBIRS is a consolidated system intended to meet United States infrared space surveillance needs for decades to come. The SBIRS program addresses critical war fighter needs in the areas of missile warning, missile defense, technical intelligence and battle space characterization.

Martin rock drill report released by NASA

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Video By NASA:

Curiosity martin rock drill report has been released, the sample was collected from Jhon Klein on Mars, which is located about 500 meters east of where we landed about 7 months ago. 
Curiosity obtained her first drill sample and passed that sample on to her on board analytical lab instruments, called CheMin and SAM. These powerful instruments tell us about what minerals are present in these rocks and whether they contain the ingredients necessary to sustain life as we know it. 

What the Curiosity team has found is incredibly exciting. When we combine what we have learned from our remote sensing and contact science instruments with the data that's coming in from CheMin and SAM, we get a picture of an ancient watery environment, which would have been habitable had life been present in it. 

As an example, the information that we're getting from the CheMin instrument, tells us that the minerals that are present in this lakebed sedimentary rock at John Klein are very different from just about anything we've ever analyzed before on Mars. And they tell us that the John Klein rock was deposited in a fresh water environment. 

This is an important contrast with other sedimentary environments that we've visited on Mars, like the Meridiani Planum landing site where the Mars Exploration Rover, Opportunity, has been operating since 2004. 
At that site, the sedimentary rocks record evidence of an environment that was only wet on a very intermittent basis, and when it was, the waters that were there were highly acidic, very salty, and not favorable for the survival of organic compounds. 
This is in direct contrast to the fresh water environment we're seeing here at the John Klein Site. 
The SAM instrument is telling us that these rocks contained all of the ingredients necessary for a habitable environment. We found carbon, sulfur and oxygen, all present and a number of other elements in states that life could have taken advantage of. 
All in all, these few tablespoons of powder from a Martian rock have provided the Curiosity science team with an exciting new dataset that tells us that Gale Crater, and perhaps all of Mars, contained habitable environments. This is an incredible success for the Curiosity mission to Gale, and the science team is looking forward to digging deeper into Mars' ancient watery past in the weeks, months, and years ahead.
Joel Hurowitz, NASA

Expedition 34 Landed Successfully

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 The scheduled landing of Expedition 34 crew members Kevin Ford, Oleg Novitskiy and Evgeny Tarelkin has been delayed 24 hours to March 16th due to bad weather in Kazakhstan.
Today,
Expedition 34 Commander Kevin A. Ford and Flight Engineers Evgeny Tarelkin and Oleg Novitskiy landed their Soyuz TMA-06M spacecraft in the steppe of Kazakhstan, northeast of the remote town of Arkalyk Friday at an estimated time of 11:08 p.m. EST. Despite fog, low visibility and below freezing temperatures Russian recovery teams were on hand to help the crew exit the Soyuz vehicle and adjust to gravity after 144 days in space. 



The trio launched aboard the Soyuz TMA-06M spacecraft from the Baikonur Cosmodrome in Kazakhstan in October and spent 142 days living and working aboard the International Space Station.
The undocking marks the end of Expedition 34 and the start of Expedition 35 under the command of Canadian Space Agency astronaut Col. Chris Hadfield, who is scheduled to remain on the station with Flight Engineers Tom Marshburn and Roman Romanenko until May. Ford ceremonially handed command of the station over to Hadfield on Wednesday. Hadfield, Marshburn and Romanenko arrived at the station aboard the Soyuz TMA-07Mspacecraft in December 2012.


Soyuz TMA-06M landing as seen from chopper:-

Landing as seen from the helicopters. After 142 days on the International Space Station, Expedition 34 crew members Kevin Ford, Oleg Novitskiy and Evgeny Tarelkin successfully touched down back on Earth in their Soyuz TMA-06M at 03:05 UTC on March 16th 2013 in Kazakhstan.



NGC 281 ( Pacman Nebula )

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NGC 281 in the optical (red, yellow) and X rays (blue)
NGC 281 (Pacman Nebula)

NGC 281 is an H II region in the constellation of Cassiopeia and part of the Perseus Spiral Arm. It includes the open cluster IC 1590, the multiple star HD 5005, and several Bok globules. Colloquially, NGC 281 is also known as the Pacman Nebula for its resemblance to the video game character.
The nebula was discovered in August 1883 by E. E. Barnard, who described it as "a large faint nebula, very diffuse." The multiple star HD 5005, also called \beta1, was discovered by S. W. Burnham. It consists of an 8th-magnitude primary with four companions at distances between 1.4 and 15.7 seconds of arc. There has been no appreciable change in this quintuple system since the first measurements were made in 1875.
The nebula is visible in amateur telescopes from dark sky locations. In his book Deep Sky Wonders, Walter Scott Houston describes the appearance of the nebula in small telescopes:

The Image: 
Young open star cluster IC 1590, which is found within the star formation region NGC 281












Image by Chandra X-ray Observatory :
Composite image of NGC 281

Smartphone app turns home drone into spacecraft

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A free European Space Agency app released today turns a popular iPhone-controlled ‘home drone’ into a spacecraft. The augmented reality game lets owners of Parrot AR.Drone quadcopters attempt dockings with a simulated International Space Station while flying their drones for real – in the process helping to improve robotic rendezvous methods.

This new AstroDrone app is part of a scientific crowdsourcing project by ESA’s Advanced Concepts Team, gathering data to teach robots to navigate their environments.


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NGC 1999

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Hubble/WFPC2 captures the void in 2000

NGC 1999 is a bright nebula filled with dust, it has empty space in the middle, showing surrounding space, as you can see in the image. It is a reflection nebula, and shines from the light of the variable star V380 Orionis.

It was previously believed that the black patch was a dense cloud of dust and gas which blocked light that would normally pass through, called a dark nebula. Analysis of this patch by the infrared telescope Herschel (October 9, 2009), which has the capability of penetrating such dense cloud material, resulted in continued black space. This led to the belief that either the cloud material was immensely dense or that an unexplained phenomenon had been detected.
It is located 1,500 light-years away from Earth in the constellation Orion.

With support from ground-based observations done using the submillimeter bolometercameras on the Atacama Pathfinder Experiment radio telescope (November 29, 2009) and the Mayall (Kitt Peak) and Magellan telescopes (December 4, 2009), it was determined that the patch looks black not because it is an extremely dense pocket of gas, but because it is truly empty. The exact cause of this phenomenon is still being investigated, although it has been hypothesized that narrow jets of gas from some of the young stars in the region punctured the sheet of dust and gas, as well as, powerful radiation from a nearby mature star may have helped to create the hole. Researchers believe this discovery should lead to a better understanding of the entire star forming process.

Credit : Wiki

California Nebula (NGC 1499)

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 California Nebula (NGC 1499)

The California Nebula (NGC 1499) is an emission nebula located in the constellation Perseus. It is so named because it appears to resemble the outline of the US State of California on long exposure photographs.because of its very low surface brightness, it is extremely difficult to observe visually. It can be observed with a H-Beta filter (isolates the H-Beta line at 486 nm) in a rich-fieldtelescope under dark skies. It lies at a distance of about 1,000 light years from Earth.
The California Nebula was discovered by E. E. Barnard in 1884.

Infrared Image of NGC 1499 by WISE

Credit : Wikipedia

Peering Deep into Jupiter's Atmosphere Cassini Spacecraft

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Peering Deep into Jupiter's Atmosphere

The dark hot spot in this false-color image from NASA's Cassini spacecraft is a window deep into Jupiter's atmosphere. All around it are layers of higher clouds, with colors indicating which layer of the atmosphere the clouds are in. The bluish clouds to the right are in the upper troposphere, or perhaps higher still, in the stratosphere. The reddish gyre under the hot spot to the right and the large reddish plume at its lower left are in the lower troposphere. In addition, a high, gauzy haze covers part of the frame. An annotated version of this image highlights the hot spot in the middle with an arrow and boxes around the plume and the gyre. 


This image was taken on Dec. 13, 2000, by Cassini's imaging science subsystem. 

The Cassini-Huygens mission is a cooperative project of NASA, the European Space Agency and the Italian Space Agency. The Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, manages the mission for NASA's Science Mission Directorate, Washington. The Cassini orbiter and its two onboard cameras were designed, developed and assembled at JPL. The imaging operations center is based at the Space Science Institute in Boulder, Colo. 

For more information about the Cassini-Huygens mission visit http://www.nasa.gov/cassini and http://saturn.jpl.nasa.gov . 

Image credit: NASA/JPL-Caltech/SSI/GSFC

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The Equatorial Region (EZ) is one of the more stable regions of the planet, in latitude and in activity. The northern edge of the EZ hosts spectacular plumes that trail southwest from the NEB, which are bounded by dark, warm (in infrared) features known as festoons (hot spots).


Zones, belts and vortices on Jupiter. The wide equatorial zone is visible in the center surrounded by two dark equatorial belts (SEB and NEB). The large grayish-blue irregular "hot spots" at the northern edge of the white Equatorial Zone change over the course of time as they march eastward across the planet. The Great Red Spot is at the southern margin of the SEB. Strings of small storms rotate around northern-hemisphere ovals. Small, very bright features, possible lightning storms, appear quickly and randomly in turbulent regions. The smallest features visible at the equator are about 600 kilometers across. This 14-frame animation spans 24 Jovian days, or about 10 Earth days. The passage of time is accelerated by a factor of 600,000. By Wikipedia



About : Expedition 35

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Expedition 35: 

Pictured on the front row are Expedition 35 Commander Chris Hadfield (right) and Flight Engineer Pavel Vinogradov. On the back row, from left, are Flight Engineers Alexander Misurkin, Chris Cassidy, Roman Romanenko and Tom Marshburn. Photo credit: NASA
Chris Hadfield was Flight Engineer in Expedition 34 and In Expedition 35 he is leading ISS as Commander.This is his third space flight of Chris Hadfield. Soyuz TMA-08M is planned to launch on March 28, 2013 and reach ISS & return on September 2013. Expedition 35 will also be only the second time an ISS crew is led by neither a NASA astronaut, nor a Roscosmos cosmonaut, after Expedition 21 in 2009, when ESA astronaut Frank de Winne was in command.
The previous Expedition 34 crew (Commander Kevin Ford of NASA, Russian Soyuz Commander Oleg Novitskiy and Russian Flight Engineer Evgeny Tarelkin ) is going to undock their Soyuz Spacecraft from ISS at 8:30 PM EDT, March 14. Landing in Kazakhstan northeast of the remote town of Arkalyk at 11:57 p.m. 

You can see live coverage of Expedition 34 landing at NASA TV. www.nasa.gov/ntv/

Info about Soyuz TMA-07M and Soyuz TMA-08M

Soyuz TMA-07M
Crew: Chris Hadfield, Tom Marshburn, Roman Romanenko
Launch:
› Dec. 19, 2012, 7:12 a.m. EST
Landing: May 2013 

Soyuz TMA-08M
Crew: Chris Cassidy, Pavel Vinogradov, Alexander Misurkin
Launch: March 28, 2013
Landing: September 2013 

Expedition 35 Mission Summary By NASA Download PDF 

ESA and Roscosmos set for mars missions

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European Space Agency and the Russian Federal Space AgencyRoscosmos, have signed a formal agreement to work in partnership on the ExoMars programme towards the launch of two missions in 2016 and 2018.

Establishing whether life ever existed on Mars is one of the outstanding scientific questions of our time and the highest scientific priority of the ExoMars programme.

The partners have agreed a balanced sharing of responsibilities for the different mission elements. ESA will provide the ExoMars Trace Gas Orbiter (TGO) and the Entry, Descent and Landing Demonstrator Module (EDM) in 2016, and the carrier and rover in 2018.

Roscosmos will be responsible for the 2018 descent module and surface platform, and will provide launchers for both missions. Both partners will supply scientific instruments and will cooperate closely in the scientific exploitation of the missions.

Crew Set for Departure from Station

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Expedition 34 Commander Kevin Ford handed command of the International Space Station over to Flight Engineer Chris Hadfield during a change of command ceremony on Wednesday. Hadfield, a veteran of the Canadian Space Agency, is the first Canadian commander of the station. 

Expedition 35 will officially begin with the undocking of the Soyuz TMA-06M spacecraft on Thursday.


Ford and Flight Engineers Evgeny Tarelkin and Oleg Novitskiy continued preparations for their journey back to Earth, stowing items and making final equipment checks. The departing trio is scheduled to undock aboard their Soyuz TMA-06M spacecraft from the station’s Poisk Mini-Research Module 2 at about 8:30 p.m. on Thursday, landing in the steppe of Kazakhstan northeast of the remote town of Arkalyk about 3 ½ hours later. 

NASA TV undocking coverage will begin Thursday at 4:45 p.m. with a crew farewell ceremony. Hatch closure between the Soyuz and station is set for 5:15 p.m. 


Chris Hadfield becomes the first Canadian commander 

James Webb Telescope Model at South by Southwest

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Click on the image for large view:
As big as a tennis court and as tall as a four-story building, a full-scale model of the James Webb Space Telescope model was on display from March 8-10 at the South by Southwest Interactive Festival in Austin, Texas. 
NASA's James Webb Space Telescope is the successor to Hubble and the largest space telescope to ever be built


The James Webb Space Telescope is a large space telescope, optimized for infrared wavelengths. It is scheduled for launch later in this decade. Webb will find the first galaxies that formed in the early Universe, connecting the Big Bang to our own Milky Way Galaxy. Webb will peer through dusty clouds to see stars forming planetary systems, connecting the Milky Way to our own Solar System. Webb's instruments will be designed to work primarily in the infrared range of the electromagnetic spectrum, with some capability in the visible range.
Webb will have a large mirror, 6.5 meters (21.3 feet) in diameter, and asunshield the size of a tennis court. The mirror and sunshade won't fit into a rocket fully open, so both will be folded and open once Webb is in outer space. Webb will reside in an orbit about 1.5 million km (1 million miles) from the Earth at the second Lagrange point.
The James Webb Space Telescope was named after a former NASA Administrator.

Image Credit: NASA

NASA Rover Finds Conditions Once Suited for Ancient Life on Mars

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Two Different Aqueous EnvironmentsThis set of images compares rocks seen by NASA's Opportunity rover and Curiosity rover at two different parts of Mars. On the left is " Wopmay" rock, in Endurance Crater, Meridiani Planum, as studied by the Opportunity rover. 

An analysis of a rock sample collected by NASA's Curiosity rover shows ancient Mars could have supported living microbes. 

Scientists identified sulfur, nitrogen, hydrogen, oxygen, phosphorus and carbon -- some of the key chemical ingredients for life -- in the powder Curiosity drilled out of a sedimentary rock near an ancient stream bed in Gale Crater on the Red Planet last month. 

"A fundamental question for this mission is whether Mars could have supported a habitable environment," said Michael Meyer, lead scientist for NASA's Mars Exploration Program at the agency's headquarters in Washington. "From what we know now, the answer is yes." 

Clues to this habitable environment come from data returned by the rover's Sample Analysis at Mars (SAM) and Chemistry and Mineralogy (CheMin) instruments. The data indicate the Yellowknife Bay area the rover is exploring was the end of an ancient river system or an intermittently wet lake bed that could have provided chemical energy and other favorable conditions for microbes. The rock is made up of a fine-grained mudstone containing clay minerals, sulfate minerals and other chemicals. This ancient wet environment, unlike some others on Mars, was not harshly oxidizing, acidic or extremely salty. 

The patch of bedrock where Curiosity drilled for its first sample lies in an ancient network of stream channels descending from the rim of Gale Crater. The bedrock also is fine-grained mudstone and shows evidence of multiple periods of wet conditions, including nodules and veins. 

Curiosity's drill collected the sample at a site just a few hundred yards away from where the rover earlier found an ancient streambed in September 2012. 

"Clay minerals make up at least 20 percent of the composition of this sample," said David Blake, principal investigator for the CheMin instrument at NASA's Ames Research Center in Moffett Field, Calif. 

These clay minerals are a product of the reaction of relatively fresh water with igneous minerals, such as olivine, also present in the sediment. The reaction could have taken place within the sedimentary deposit, during transport of the sediment, or in the source region of the sediment. The presence of calcium sulfate along with the clay suggests the soil is neutral or mildly alkaline. 

Scientists were surprised to find a mixture of oxidized, less-oxidized, and even non-oxidized chemicals, providing an energy gradient of the sort many microbes on Earth exploit to live. This partial oxidation was first hinted at when the drill cuttings were revealed to be gray rather than red. 

"The range of chemical ingredients we have identified in the sample is impressive, and it suggests pairings such as sulfates and sulfides that indicate a possible chemical energy source for micro-organisms," said Paul Mahaffy, principal investigator of the SAM suite of instruments at NASA's Goddard Space Flight Center in Greenbelt, Md. 

An additional drilled sample will be used to help confirm these results for several of the trace gases analyzed by the SAM instrument. 

"We have characterized a very ancient, but strangely new 'gray Mars' where conditions once were favorable for life," said John Grotzinger, Mars Science Laboratory project scientist at the California Institute of Technology in Pasadena, Calif. "Curiosity is on a mission of discovery and exploration, and as a team we feel there are many more exciting discoveries ahead of us in the months and years to come." 

Scientists plan to work with Curiosity in the "Yellowknife Bay" area for many more weeks before beginning a long drive to Gale Crater's central mound, Mount Sharp. Investigating the stack of layers exposed on Mount Sharp, where clay minerals and sulfate minerals have been identified from orbit, may add information about the duration and diversity of habitable conditions. 

NASA's Mars Science Laboratory Project has been using Curiosity to investigate whether an area within Mars' Gale Crater ever has offered an environment favorable for microbial life. Curiosity, carrying 10 science instruments, landed seven months ago to begin its two-year prime mission. NASA's Jet Propulsion Laboratory in Pasadena, Calif., manages the project for NASA's Science Mission Directorate in Washington. 

Source : JPL.NASA.GOV