Posted on by Tammy Plotner

Taking Mars’ Temperature – The ALH84001 Meteorite

This photograph shows globules of orange-colored carbonate minerals found in the Martian meteorite dubbed ALH84001. The origin of the carbonate minerals has long puzzled scientists, but by determining that the carbonate formed at about 18 degrees Celsius, Caltech researchers say they might have an answer. The mild temperature is also consistent with the theory that Mars was once warmer and wetter than it is today. Credit: NASA

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It might be four billion years old, but this meteorite which may have originated near the surface of Mars has a story to tell… one about a warmer and wetter history. Researchers at the California Institute of Technology (Caltech) have been analyzing the carbonate minerals contained within the Martian meteorite – ALH84001- and piecing together a climate history which showed the minerals formed at about 18 degrees Celsius (64 degrees Fahrenheit).

“The thing that’s really cool is that 18 degrees is not particularly cold nor particularly hot,” says Woody Fischer, assistant professor of geobiology and coauthor of the paper, published online in the Proceedings of the National Academy of Sciences (PNAS) on October 3. “It’s kind of a remarkable result.”

All recent studies, from rovers to spectroscopy, point to Mars having once had a much more temperate climate than its current average temperature of -63 degrees Celsius. Missions have photographed dry river beds, deltas, extinct lakes and more. Up until now, the one crucial point has been the lack of physical evidence. “There are all these ideas that have been developed about a warmer, wetter early Mars,” Fischer says. “But there’s precious little data that actually bears on it.” That is, until now.

Of course, this mineralogical evidence is strictly one point – but it’s one point closer to knowing the full score. “It’s proof that early in the history of Mars, at least one place on the planet was capable of keeping an Earth-like climate for at least a few hours to a few days,” says John Eiler, the Robert P. Sharp Professor of Geology and professor of geochemistry, and a coauthor of the paper. The first author is Itay Halevy, a former postdoctoral scholar who’s now at the Weizmann Institute of Science in Israel.

Where did this new evidence come from? Try ALH84001, a Martian meteorite discovered in 1984 in the Allan Hills of Antarctica. While scientists cannot definitely prove where it came from, ALH84001 is theorized to have once originated several hundred feet below the Martian surface and was blown Earthward during an impact event. The Martian meteorite made headlines in 1996 when little inclusions that appeared to be fossilized bacteria were discovered. Even though the thought of simple life forms were quickly shot down, the pockets which contained carbonate minerals remained an enigma.

“It’s been devilishly difficult to work out the process that generated the carbonate minerals in the first place,” Eiler says. But there have been countless hypotheses, he adds, and they all depend on the temperature in which the carbonates formed. Some scientists say the minerals formed when carbonate-rich magma cooled and crystallized. Others have suggested that the carbonates grew from chemical reactions in hydrothermal processes. Another idea is that the carbonates precipitated out of saline solutions. The temperatures required for all these processes range from above 700 degrees Celsius in the first case to below freezing in the last. “All of these ideas have merit,” Eiler says.

Deducing the temperature may help scientists to understand how the carbonates came to be, so a form of modeling called clumped-isotope thermometry was employed to help. It’s so sensitive it’s able to determine a dinosaur’s body temperature in relation to Earth’s climate history. In this case, the team measured concentrations of the rare isotopes oxygen-18 and carbon-13 contained in the carbonate samples. Carbonate is made out of carbon and oxygen, and as it forms, the two rare isotopes may bond to each other – clumping together, as Eiler calls it. As the temperature progressively lowers, the isotopes do their thing and clump. The degree to which this happens is directly related to temperature. The temperature the researchers measured – 18 ± 4 degrees Celsius – rules out many carbonate-formation hypotheses. “A lot of ideas that were out there are gone,” Eiler says. For one, the mild temperature means that the carbonate must have formed in liquid water. “You can’t grow carbonate minerals at 18 degrees other than from an aqueous solution,” he explains.

Through this new information, it is also hypothesized the minerals may have come into existence inside the cavities of rock while it was below ground. “As the water evaporated, the rock outgassed carbon dioxide, and the solutes in the water became more concentrated. The minerals then combined with dissolved carbonate ions to produce carbonate minerals, which were left behind as the water continued to evaporate.” A vessel for life? Well, chances aren’t good since any liquid water would have lasted for only a brief time – but it is a great indicator that this precious life-giver was once a part of Mars’ history.

Original Story Source: Caltech News Release.

Posted on by Ray Sanders

NASA to Test New Solar Sail Technology

The Solar Sail demonstration mission. Credit: NASA

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Solar sails, much like anti-matter and ion engines appear at first glance to only exist in science fiction. Many technologies from science fiction however, become science fact.

In the example of solar sails, perfecting the technology would allow spacecraft to travel through our solar system using very little fuel.

NASA has been making strides with solar sail technology. Using the NanoSail-D mission, NASA continues to gather valuable data on how well solar sails perform in space. The Planetary Society will also be testing solar sail technology with their LightSail-1 project sometime next year.

How will NASA (and others) test solar sail technology, and develop it into a common, reliable technology?

The second of three recently announced technology demonstrations, The Solar Sail Demonstration, will test the deployment of a solar sail in space along with testing attitude control. The solar sail will also execute a navigation sequence with mission-capable accuracy.

In order to make science fiction into reality, NASA engineers are testing solar sails that could one day provide the propulsion for deep space missions. Spacecraft using solar sails would travel in our solar system in a similar manner to a sailboat through water, except spacecraft using solar sails would rely on sunlight instead of wind. A spacecraft propelled by a solar sail would use the sail to capture photons emitted from the Sun. Over time, the buildup of the solar photons provides enough thrust for a small spacecraft to travel in space.

NASA’s solar sail demonstration mission will deploy and operate a sail area 7 times larger than ever flown in space. The technology used in the demonstration will be applicable to many future space missions, including use in space weather warning systems to provide timely and accurate warnings of solar flare activity. The solar sail demonstration is a collaborative effort between The National Oceanic and Atmospheric Administration (NOAA), NASA and contractor L’Garde Inc.

NASA lists several capabilities solar sails have to offer, such as:

  • Orbital Debris: Orbital debris can be captured and removed from orbit over a period of years using the small solar-sail thrust.
  • De-orbit of spent satellites: Solar sails can be integrated into satellite payloads so that the satellite can be de-orbited at the end of its mission.
  • Station keeping: Using the low propellantless thrust of a solar sail to provide station keeping for unstable in-space locations.
  • Deep space propulsion: Payloads free of the Earth’s pull can be continuously and efficiently accelerated to the other planets, or out of the solar system, such as proposed in Project Encounter.

    • As an example, the GeoStorm project considers locating solar storm warning satellites at pseudo Lagrange points three times further from the Earth by using the solar sail to cancel some solar gravitational pull, thus increasing warning time from ~15 minutes to ~45 minutes.

    Providing a satellite with a persistent view of northern or southern latitudes, i.e., a “pole-sitter” project. This allows the observational advantages of today’s geosynchronous satellites for orbits with view angles of the northern and southern high-latitudes.

    A solar sail system, measuring 66 feet on each side was tested in 2005 in the world's largest vacuum chamber. Image Credit: NASA

    If you’d like to learn more about solar sails, Caltech has a nice “Solar Sailing 101” page at: http://www.ugcs.caltech.edu/~diedrich/solarsails/intro/intro.html

    Source: NASA Technology Demonstration Mission Updates

    Posted on by Ken Kremer

    Daring Russian Sample Return mission to Martian Moon Phobos aims for November Liftoff

    Russian Phobos-Grunt spacecraft set to Launch in November 2011.The flight version of the Phobos-Grunt spacecraft minus its main solar panels is being lowered into a vacuum chamber at NITs RKP test facility in Peresvet, north of Moscow, for thermal, vacuum and electric tests around beginning of June 2011. Credit: NPO Lavochkin

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    In just over 3 weeks’ time, Russia plans to launch a bold mission to Mars whose objective, if successful , is to land on the Martian Moon Phobos and return a cargo of precious soil samples back to Earth about three years later.

    The purpose is to determine the origin and evolution of Phobos and how that relates to Mars and the evolution of the solar system.

    Liftoff of the Phobos-Grunt space probe will end a nearly two decade long hiatus in Russia’s exploration of the Red Planet following the failed Mars 96 mission and is currently scheduled to head to space just weeks prior to this year’s other Mars mission – namely NASA’s next Mars rover, the Curiosity Mars Science Laboratory (MSL).

    Blastoff of Phobos-Grunt may come as early as around Nov. 5 to Nov. 8 atop a Russian Zenit 3-F rocket from the Baikonur Cosmodrome in Kazakhstan. The launch window extends until about Nov. 25. Elements of the spacecraft are undergoing final prelaunch testing at Baikonur.

    Flight version of the Phobos-Grunt spacecraft during assembly in preparation for critical testing in thermal and vacuum chamber at NITs RKP facility closely imitating harsh conditions of the real space flight. Credit: NPO Lovochkin

    Baikonur is the same location from which Russian manned Soyuz rockets lift off for the International Space Station. Just like NASA’s Curiosity Mars rover, the mission was originally intended for a 2009 launch but was prudently delayed to fix a number of technical problems.

    “November will see the launch of the Phobos-Grunt interplanetary automatic research station aimed at delivering samples of the Martian natural satellite’s soil to Earth’” said Vladimir Popovkin, head of the Russian Federal Space Agency, speaking recently at a session of the State Duma according to the Voice of Russia, a Russian government news agency.

    Phobos-Grunt spacecraft

    The spacecraft will reach the vicinity of Mars after an 11 month interplanetary cruise around October 2012. Following several months of orbital science investigations of Mars and its two moons and searching for a safe landing site, Phobos-Grunt will attempt history’s first ever touchdown on Phobos. It will conduct a comprehensive analysis of the surface of the tiny moon and collect up to 200 grams of soil and rocks with a robotic arm and drill.

    Russian Phobos-Grunt spacecraft prepares for testing inside the vacuum chamber. Credit: NPO Lavochkin

    After about a year of surface operations, the loaded return vehicle will blast off from Phobos and arrive back at Earth around August 2014. These would be the first macroscopic samples returned from another body in the solar system since Russia’s Luna 24 in 1976.

    “The way back will take between nine and 11 months, after which the return capsule will enter Earth’s atmosphere at a speed of 12 kilometers per second. The capsule has neither parachute nor radio communication and will break its speed thanks to its conical shape,” said chief spacecraft constructor Maksim Martynov according to a report from the Russia Today news agency. He added that there are two soil collection manipulators on the lander because of uncertainties in the characteristics of Phobos soil.

    Phobos-Grunt was built by NPO Lavochkin and consists of a cruise stage, orbiter/lander, ascent vehicle, and Earth return vehicle.

    The spacecraft weighs nearly 12,000 kg and is equipped with a sophisticated 50 kg international science payload, in particular from France and CNES, the French Space Agency.

    Also tucked aboard is the Yinghou-1 microsatellite supplied by China. The 110 kg Yinghou-1 is China’s first probe to launch to Mars and will study the Red Planet’s magnetic and gravity fields and surface environment from orbit for about 1 year.

    “It will be the first time such research [at Mars] will be done by two spacecraft simultaneously. The research will help understand how the erosion of Mars’ atmosphere happens,” said Professor Lev Zelyony from the Space Research Institute of the Russian Academy of Science, according to Russia Today.

    Phobos-Grunt mission scenario. Credit: CNES
    Phobos seen by Mars Express. Credit: ESA

    Read Ken’s continuing features about Phobos-Grunt, Curiosity and Opportunity starting here:
    Assembling Curiosity’s Rocket to Mars
    Encapsulating Curiosity for Martian Flight Test
    Dramatic New NASA Animation Depicts Next Mars Rover in Action
    Opportunity spotted Exploring vast Endeavour Crater from Mars Orbit
    Twin Towers 9/11 Tribute by Opportunity Mars Rover
    NASA Robot arrives at ‘New’ Landing Site holding Clues to Ancient Water Flow on Mars
    Opportunity Arrives at Huge Martian Crater with Superb Science and Scenic Outlook
    Opportunity Snaps Gorgeous Vistas nearing the Foothills of Giant Endeavour Crater
    Opportunity Rover Heads for Spirit Point to Honor Dead Martian Sister; Science Team Tributes

    Posted on by Jason Rhian

    Sierra Nevada’s Dream Chaser to Conduct Drop Test Next Summer

    Sierra Nevada Corporation is set to conduct a high-altitude free-flight test of the company's dream Chaser space plane as early as this summer. Image Credit: SNC

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    It looks as though the efforts to get commercial space taxis off the ground – is succeeding. Sierra Nevada Corporation’s (SNC) “Dream Chaser” space plane is slated to conduct its first test flight as early as next summer. SNC is one of four companies that have had proposals selected by NASA under the Commercial Crew Development Program – 02 (CCDev2).

    The test flight, what is known as a high-altitude free-flight test or “drop-test” will see Dream Chaser lifted high into the air, where the craft will then be released from its carrier aircraft and attempt an unmanned landing. During the course of this flight test program SNC will test out the space plane’s autoland and other capabilities.

    The Dream Chaser space plane is derived from the HL-20 lifting body developed by NASA. Photo Credit: SNC

    “Sierra Nevada Space Systems is honored to be awarded an additional $25.6 million by NASA as part of the second round of the Commercial Crew Development Program (CCDev2), bringing the total award to $105.6 million for this round of the competition,” said Mark Sirangelo, head of Sierra Nevada Space Systems. “As part of CCDev2, the Program has already completed four of the planned milestones, on time and on budget. The now thirteen CCDev2 milestones will culminate in a high-altitude free-flight test of our vehicle in the summer of 2012. ”

    With NASA’s fleet of orbiters retired and being prepared to go on display in museums, NASA is dependent on the Russian Soyuz for access to the International Space Station (ISS). NASA currently pays Russia $63 million per seat for trips to the orbiting laboratory.

    If all goes according to plan, the Dream Chaser could be one of many 'space-taxis' that would supply transportation services to the International Space Station. Image Credit: SNC

    Many within both NewSpace and established space companies have stated their intent on reducing the amount of time that the U.S. is in such a position. NASA also has worked to assist companies that are working on CCDev2 to either meet or exceed their deadlines.
    NASA is hopeful that these developments will allow the space agency to turn over transportation to the ISS to commercial firms by 2016.

    In the case of SNC, NASA increased what the company was paid by an added $25.6 million. SNC had already been awarded $80 million as their part of the CCDev2 contract. After this boost in funding, SNC announced that the drop test would be held next summer.
    The Dream Chaser design is based primarily off of the HL-20 lifting body design and is capable of carrying seven astronauts to orbit. Dream Chaser is designed to launch from Cape Canaveral Air Force Station located in Florida atop a United Launch Alliance (ULA) Atlas V 402.

    Sierra Nevada Corporation is working steadily to test out and prove the Dream Chaser's various systems. Photo Credit: SNC

    If everything goes according to how it is currently planned, the test flight will take place at either Edwards Air Force Base, located in California or White Sands Missile Range in New Mexico. Virgin Galactic’s WhiteKnightTwo will carry the Dream Chaser space plane aloft for the test. Virgin Galactic, another NewSpace firm, is based in the U.S. and owned by Sir Richard Branson.

    The ISS is viewed by the U.S, and the 15 other nations involved with the project as a crucial investment and having only one way to send crew to and from the ISS as being unacceptable. Sierra Nevada’s Dream Chaser is joined by Space Exploration Technologies’ (SpaceX) Dragon spacecraft, Boeing’s CST-100 and Blue Origin’s as-yet unnamed spacecraft in the CCDev2 contract.

    The Dream Chaser space plane atop a United Launch Alliance Atlas V rocket. Image Credit: SNC
    Posted on by Paul Scott Anderson

    Mystery of the Martian Rilles

    Credit: ASU / NASA / JPL

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    When the first spacecraft flew by Mars in the 1960’s, the images returned revealed a relatively uninteresting-looking place, featureless in some areas and pockmarked with craters in most others. It looked a lot like the Moon. Later flybys and orbiting probes, however, gave us a closer look at other regions on the planet, providing a glimpse of what Mars is really like: a world of mountains, volcanoes, canyons, craters, old riverbeds and polar ice caps. It is little surprise then, that these striking geologic features captured scientists’ attention the most, and so areas like Hesperia Planum, a flat, relatively dull-looking plain, have received less attention over the years.

    But there is a mystery in this region in the form of geologic features called rilles. No one has been able to figure out where they came from or how they formed.

     The rilles in Herperia Planum are a series of about a dozen narrow, sinuous channels. They are up to a few hundred meters wide, and hundreds of kilometers long, but don’t appear to have any sources or destinations. The assumption has been that they were most likely created by lava flows, like their counterparts on the Moon. But apart from one very small volcano, there is little evidence of any volcanism in Hesperia Planum, which makes the appearance these rilles difficult to explain.

    Another explanation could be water, but again, there are no obvious sources or other indications of past water in this region.

    These enigmatic features have been the subject of study by scientists from the University at Buffalo, State University of New York. Geologist Tracy Gregg and her student Carolyn Roberts have been comparing them to rilles on the Moon, and their preliminary findings were presented today at the Annual Meeting of The Geological Society of America, in Minneapolis, and they hope to find some answers in further study and collaboration with other scientists.

    “On the Moon we see these same kinds of features and we know that water couldn’t have formed them there,” Gregg said. “Everybody assumed these were huge lava flows, But if it turns out to be a lake deposit, it’s a very different picture of what Mars was doing at that time.”

    So, were they formed by water, lava or something else? If it turned out to be water, that would of course be more interesting in terms of the search for possible habitable areas in Mars’ past.

    Whichever explanation turns out to be correct, or even a different one, it will be one more piece of evidence which helps to further our understanding of this fascinating world, so much like our own in some ways, yet utterly alien in others

    The paper is available here and additional photos are here.

    Source: EurekAlert

    Posted on by Ray Sanders

    NASA to Test Laser Communications System

    Conceptual image of The Laser Communications Relay Demonstration. Credit: NASA

    [/caption]Quite often, communication rates with remote spacecraft have been a limiting factor when exploring our solar system. For example, it can take up to 90 minutes to transfer one high-resolution image from the Mars Reconnaissance Orbiter to scientists on Earth.

    Improving data communication rates would allow scientists to collect additional data from future missions to Mars, Titan or other destinations in our solar system.

    How does NASA plan to overcome the current limitations in communication with spacecraft outside Earth orbit?

    One of three recently announced technology demonstrations, The Laser Communications Relay Demonstration, will help demonstrate and validate laser-based communications. One of many goals for the LCRD is to provide spacecraft in Earth orbit ( and beyond ) a faster and reliable method of communication than standard radio communications currently in use.

    A laser-based communication will allow NASA and other government agencies to perform missions that require higher data rates. In the cases where less data is required, the laser-based systems would consume less power, mass and precious volume inside a spacecraft. Given roughly equal mass, power, and volume, the laser-based communications system offers much higher data rates than a radio-based communications system.

    NASA’s goals for the LCRD are to:

    Enable reliable, capable, and cost effective optical communications technologies for near earth applications and provide the next steps required toward optical communications for deep space missions

    Demonstrate high data rate optical communications technology necessary for:

  • Near-Earth spacecraft (bi-directional links supporting hundreds of Mbps to Gbps)
  • Deep Space missions (tens to hundreds of Mbps from distances such as Mars and Jupiter)
  • Develop, validate and characterize operational models for practical optical communications
  • Identify and develop requirements and standards for future operational optical communication systems
  • Establish a strong partnership with multiple government agencies to facilitate crosscutting infusion of optical communications technologies
  • Develop the industrial base and transfer technology for future space optical communications systems

    • High-rate communications 10-100 times more capable than current radio systems will also allow for greatly improved connectivity and enable new generations of remote missions that are far more capable than today’s missions. NASA’s LCRD will also provide the satellite communication industry with technology not available today. Laser-based space communications will enable missions to use high-definition video and and pave the way for a possible “virtual presence” on a remote planet or other bodies in the solar system.

    While the laser-based communications technology featured in the LCRD will allow more data to be sent from spacecraft to scientists on Earth, the communication delays (a few seconds for the Moon, and over twenty minutes for Mars) will still require careful mission planning.

    Diagram of LCRD mission. Image Credit: NASA

    The Laser Communications Relay Demonstration (LCRD) is led by the NASA Goddard Space Flight Center. Space Communications and Navigation (SCaN) office in the Human Exploration and Operations Mission Directorate is collaborating with the NASA Office of the Chief Technologist in sponsoring this technology demonstration.

    If you’d like to learn more about NASA’s LCRD, you can read more at: http://www.nasa.gov/topics/technology/features/laser-comm.html

    Source: NASA Technology Demonstration Updates

    Posted on by Tammy Plotner

    Early Galaxies – Clearing The “Cosmic Fog”

    Scientists have used ESO’s Very Large Telescope to probe the early Universe at several different times as it was becoming transparent to ultraviolet light. This brief but dramatic phase in cosmic history — known as reionisation — occurred around 13 billion years ago. By carefully studying some of the most distant galaxies ever detected, the team has been able to establish a timeline for reionisation for the first time. They have also demonstrated that this phase must have happened quicker than astronomers previously thought.

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    The seasons are changing for both hemispheres and it’s not uncommon to wake up to wonderful, mysterious swirls of fog. What we experience here on Earth is water vapor, but the Universe was once filled with a fog of hydrogen gas. As the hours progress, the Sun slowly burns it off – quietly revealing trees, houses and the road ahead. In time after expansion began, the electrically neutral hydrogen gas was slowly swept away by the light of ultraviolet radiation from early galaxies…

    Using the Very Large Telescope (VLT) like a “time machine”, a team of astronomers cut through the cosmic cloud layer to view some of the most distant galaxies recorded so far – a look back between 780 million and a billion years after the Big Bang. These antediluvian galaxies excited the gas, making it electrically charged (ionised), it gradually became transparent to ultraviolet light. While you may argue this process is technically known as reionization, there is theorized to be a brief timeline when hydrogen was also ionised.

    “Archaeologists can reconstruct a timeline of the past from the artifacts they find in different layers of soil. Astronomers can go one better: we can look directly into the remote past and observe the faint light from different galaxies at different stages in cosmic evolution,” explains Adriano Fontana, of INAF Rome Astronomical Observatory who led this project. “The differences between the galaxies tell us about the changing conditions in the Universe over this important period, and how quickly these changes were occurring.”

    As we know from spectroscopy, each element has its own signature – the emission lines – and the strongest in ultraviolet is the Lyman-alpha line generated from hydrogen. This bold spectral signature is easily recognizable – even at a vast distance. By observing the Lyman-alpha line for five very remote galaxies, the team was able to establish two critical factors: their distance through redshift and how soon they could be detected. Through this process, the astronomers were then able to establish how much the Lyman-alpha emission was reabsorbed by the neutral hydrogen fog and create a timeline… A whole lot like recording what minute each landmark reappears when terrestrial fog clears and seeing the long road ahead.

    “We see a dramatic difference in the amount of ultraviolet light that was blocked between the earliest and latest galaxies in our sample,” says lead author Laura Pentericci of INAF Rome Astronomical Observatory. “When the Universe was only 780 million years old this neutral hydrogen was quite abundant, filling from 10 to 50% of the Universe’ volume. But only 200 million years later the amount of neutral hydrogen had dropped to a very low level, similar to what we see today. It seems that reionization must have happened quicker than astronomers previously thought.”

    As always, there’s a bit more to the story. In this case, by understanding the rate at which the ancient absorbent obstruction began fading, scientists could also deduce the source of the powerful ultraviolet radiation. Could it be first generation stars – or even the work of primeval black holes?

    “The detailed analysis of the faint light from two of the most distant galaxies we found suggests that the very first generation of stars may have contributed to the energy output observed,” says Eros Vanzella of the INAF Trieste Observatory, a member of the research team. “These would have been very young and massive stars, about five thousand times younger and one hundred times more massive than the Sun, and they may have been able to dissolve the primordial fog and make it transparent.”

    To prove anything, it’s going to take a lot more research and some very accurate measurements – ones that are already in the planning stage for the future ESO European Extremely Large Telescope. But, in the meantime, the team used the great light-gathering power of the 8.2-metre VLT to carry out spectroscopic observations, targeting galaxies first identified by the NASA/ESA Hubble Space Telescope and in deep images from the VLT.

    Original Story Source: ESO Press Release. For Further Reading: Probing The Earliest Galaxies And The Epoch Of Reionization.

    Posted on by Nancy Atkinson

    Where In The Universe Challenge #153

    Here’s a new WITU Challenge! Take a look at this image and see if you can determine where in the universe this image is from; give yourself extra points if you can name the spacecraft/telescope responsible for the image. We’ll provide the image today, but won’t reveal the answer until tomorrow. This gives you a chance to mull over the image and provide your answer/guess in the comment section. Please, no links or extensive explanations of what you think this is — give everyone the chance to guess.

    Remember, we’ll take suggestions for future WITU’s — just send Nancy an email

    UPDATE: The answer has now been posted below.

    This eye-shaped object is the Planetary Nebula NGC 6826, and the image was taken by the Hubble Space Telescope on Jan. 27, 1996 with the Wide Field and Planetary Camera 2. NGC 6826 is 2,200 light- years away in the constellation Cygnus, and the hot remnant star in the center of the green oval is one of the brightest stars in any planetary nebula. See more about this image on the HubbleSite.

    Posted on by Jason Rhian

    Bolden Visits Kennedy Space Center, Talks SLS and the Future

    Kennedy Space Center Director Bob Cabana introduces NASA Administrator Charles Bolden in front of the Mobile Launch Platform at Kennedy Space Center in Florida. Photo Credit: Suresh Atapattu

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    CAPE CANAVERAL, Fla – NASA Administrator Charles Bolden stopped by Kennedy Space Center in Florida to tour NASA’s Mobile Launch Platform. Bolden was joined by fellow former shuttle astronaut and current Kennedy Space Center Director Robert Cabana. The duo toured the 355-foot-tall structure Tuesday, Oct. 11 at 11 a.m. EDT.

    The Mobile Launcher’s future was in doubt after the Constellation Program was cancelled. Although nothing definite was stated – everything from scrapping the structure, using it as a platform for tourists at the Kennedy Space Center Visitor Center to just keeping it in reserve was suggested. The space agency now plans to use the structure to launch the Space Launch System or SLS rocket.

    NASA Kennedy Space Center Director Bob Cabana (far left) gestures while discussing how the MLP will be used in upcoming missions. To his left is NASA Administrator Charles Bolden and they are surrounded by members of the local media. Photo Credit: Suresh Atapattu

    The NASA administrator’s visit was designed to help promote NASA’s recently-unveiled SLS heavy-lift rocket. The launch vehicle somewhat resembles a cross between the cancelled Ares V and the Saturn V moon rockets that launched Apollo astronauts to the moon. It is slated to begin conducting flights by 2017. SLS is comprised primarily of so-called “legacy hardware” – proven technology derived from the space shuttle and Saturn systems.

    Bolden spent some time chatting with reporters and working to reassure Kennedy Space Center’s remaining workforce, as well as several hundred Space Coast community and business leaders and elected officials that the area’s future was bright. Bolden used the visit to state that this was a sign that things were improving in the region. He highlighted the fact that new capabilities, such as the placement of the Commercial Crew program office at Kennedy, will help to maintain aerospace skills and capabilities.

    NASA Administrator Charles Bolden descends the steps of the MLP during his visit to Kennedy Space Center on Oct. 11, 2011. Photo Credit: Suresh Atapattu

    “As our nation looks for ways to compete and win in the 21st century, NASA continues to be an engine of job growth and economic opportunity,” Bolden said. “From California to Florida, the space industry is strong and growing. The next generation of explorers will
    not fly a space shuttle, but they may be able to walk on Mars. And those journeys are starting at the Kennedy Space Center today.”

    The shuttle elements of SLS include the RS-25 engines (Space Shuttle Main Engines) along with modified versions of the Solid Rocket Boosters that were employed on the space shuttle. The Saturn elements (descendent) are the J-2X engines, which are simpler variants of the J-2 engines employed during the Apollo era.

    A few up the massive Mobile Launch Platform and Mobile Launch Tower (the combined structure is generally called the Mobile Launcher). Photo Credit: Julian Leek/Blue Sawtooth Studios

    NASA made its plans for the SLS public in September, just one day after Alliant Techsystems (ATK) and NASA announced that an unfunded Space Act Agreement deal to study the viability of using the Liberty rocket to ferry astronauts to orbit. If all goes according to plan, SLS will eventually be utilized to launch the Orion Multi-Purpose Crew Vehicle. It is hoped that the introduction of SLS and other space systems will help to stem the flow of highly-trained and experienced workers from the space agency.