Thursday, 6 March 2014

Plasma plumes help shield Earth from damaging solar storms

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Scientists have identified a plasma plume that naturally protects the Earth against solar storms. Earth's magnetic field, or magnetosphere, stretches from the planet's core out into space, where it meets the solar wind, a stream of charged particles emitted by the sun. For the most part, the magnetosphere acts as a shield to protect Earth from this high-energy solar activity. But when this field comes into contact with the sun's magnetic field -- a process called "magnetic reconnection" -- powerful electrical currents from the sun can stream into Earth's atmosphere, whipping up geomagnetic storms and space weather phenomena that can affect high-altitude aircraft, as well as astronauts on the International Space Station. Now scientists have identified a process in Earth's magnetosphere that reinforces its shielding effect, keeping incoming solar energy at bay.

via Science Daily

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Storing extra rocket fuel in space for future missions?

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Future lunar missions may be fueled by gas stations in space, according to engineers: A spacecraft might dock at a propellant depot, somewhere between the Earth and the moon, and pick up extra rocket fuel before making its way to the lunar surface. Orbiting way stations could reduce the fuel a spacecraft needs to carry from Earth -- and with less fuel onboard, a rocket could launch heavier payloads, such as large scientific experiments.

via Science Daily

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Hubble witnesses an asteroid mysteriously disintegrating

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The NASA/ESA Hubble Space Telescope has photographed the never-before-seen break-up of an asteroid, which has fragmented into as many as ten smaller pieces. Although fragile comet nuclei have been seen to fall apart as they approach the Sun, nothing like the breakup of this asteroid, P/2013 R3, has ever been observed before in the asteroid belt.

via Science Daily

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Hubble Witnesses an Asteroid Mysteriously Disintegrating



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Though fragile comet nuclei have been seen falling apart as they near the Sun, nothing like the slow breakup of an asteroid has ever before been observed in the asteroid belt. A series of Hubble Space Telescope images shows that the fragments are drifting away from each other at a leisurely one mile per hour. This makes it unlikely that the asteroid is disintegrating because of a collision with another asteroid. A plausible explanation is that the asteroid is crumbling due to a subtle effect of sunlight. This causes the rotation rate to slowly increase until centrifugal force pulls the asteroid apart. The asteroid's remnant debris, weighing in at 200,000 tons, will in the future provide a rich source of meteoroids.




via HubbleSite NewsCenter -- Latest News Releases

http://hubblesite.org/newscenter/archive/releases/2014/15/

Astronomers witness mysterious, never-before-seen disintegration of asteroid

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Astronomers have witnessed for the first time the breakup of an asteroid into as many as 10 smaller pieces. The discovery is published online March 6 in Astrophysical Journal Letters.



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NGC 1333 Stardust

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NGC 1333 is seen in visible light as a reflection nebula, dominated by bluish hues characteristic of starlight reflected by dust. A mere 1,000 light-years distant toward the heroic constellation Perseus, it lies at the edge of a large, star-forming molecular cloud. This striking close-up view spans about two full moons on the sky or just over 15 light-years at the estimated distance of NGC 1333. It shows details of the dusty region along with hints of contrasting red emission from Herbig-Haro objects, jets and shocked glowing gas emanating from recently formed stars. In fact, NGC 1333 contains hundreds of stars less than a million years old, most still hidden from optical telescopes by the pervasive stardust. The chaotic environment may be similar to one in which our own Sun formed over 4.5 billion years ago.

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Lava floods the ancient plains of Mars

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Two distinct volcanic eruptions have flooded this area of Daedalia Planum with lava, flowing around an elevated fragment of ancient terrain.




via ESA Space Science

http://www.esa.int/Our_Activities/Space_Science/Mars_Express/Lava_floods_the_ancient_plains_of_Mars

Chemically and structurally functionalized graphene for real-world applications

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After ten years of discovering the amazing properties of pristine graphene and seeking its uses in electronics, photonics, and novel technologies, researchers are starting to add another layer to the beautifully complex world of graphene: chemically functionalized and nanostructured graphene.



The use of graphene for water desalination is back to the spotlight, after recent reports on controllable manufacture of nanopores in graphene films. Last April we wrote about a theoretical simulation, done at MIT, which showed that graphene with pores having a ~1 nanometer diameter would act as an excellent water filter, passing clean water while leaving behind any chemical residue. The news of MIT's discovery was so big that the Smithsonian magazine, the publication of the famous Smithsonian Institution, named it one of the top 5 surprising scientific milestones of 2012 Nanometer-sized pores in graphene films are not only considered for water filtration, but also for rapid DNA sequencing, given that the lateral size of a DNA strand is about one nanometer.



Now, less than a year later, we are seeing first reports of sub-nanometer sized holes made controllably in graphene. At the beginning of February, we reported on our recent publication, together with Harvard University, the Lawrence Berkeley National Lab and FEI Corporation, in which we show movies of the creation of pores in a graphene film. The pores are catalyzed by residual silicon atoms and range in size from several angstroms to a few nanometers. The placement of the silicon atoms occurs randomly. Researchers at MIT have taken technology even further, showing that they can place nanopores at desired locations on the sheet. The nanopores are initiated by bombarding the sheet with gallium ions from a focused ion beam. The location of the bombardment target can be placed with nanometer accuracy, leading to graphene sheets with 5 trillion pores per square centimeter, each placed deterministically, all being of similar size.




Figure: MIT researchers bombard graphene sheets with ions, crafting a set of nanopores. Copyright: American Chemical Society.




Both papers were published in the journal Nano Letters, and both papers make use of high-resolution charged-particle microscopy. The work which Graphenea coauthored uses high-resolution transmission electron microscopy to initiate the chemical catalysis, whereas the work performed at MIT makes use of a focused ion beam. It seems that using graphene in such microscopes is gaining popularity, not only for fabrication of small holes, but also for aiding imaging. At the beginning of February, a report in the journal Advanced Materials showcased a novel use of graphene. Scientists at Michigan Technological University and the University of Illinois Chicago used graphene to encapsulate a drop of liquid, enabling the first electron-beam imaging of liquids. The ability to image liquids at the extreme resolution provided by an electron-beam microscope will have strong implications for biology and medicine, which so far relied on imaging frozen and thinly sliced biological samples.



Other recent research points out the importance of chemically functionalized and nanostructured graphene. Notably, researchers in Vienna have shown that Calcium-doped graphene can have superconducting properties. While the predicted critical temperature of 1.5 Kelvin does not set any world records (fullerenes, a carbon cousin of graphene, exhibit a critical temperature of 33K), researchers are confident that the ease of doping and local control of graphene sheets will provide additional flexibility compared to other superconducting materials. Researchers at the Brookhaven National Lab, on the other hand, studied the intercalation of Cesium atoms in graphene. They found that the intercalation is adjusted by the short-range van der Waals interaction, with the dynamics governed by defects anchored to graphene wrinkles. Then, by controlling intercalation, the scientists were able to create p-n junctions at desired locations in graphene. P-n junctions are integral parts of electronic components such as diodes and transistors, as well as some photodetectors. Also, well-defined nanoscale ferromagnetic islands underneath the graphene were built.



Finally, the Journal of Physics D published a special issue on commercialization of graphene. The edition, appropriately entitled “Graphene: from functionalization to devices”, once again underlines the importance of chemical and structural functionalization of graphene as it transforms from the amazing lab material to an enabling component of novel technologies.




via Graphenea

New robotic refueling technologies tested

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NASA has successfully concluded a remotely controlled test of new technologies that would empower future space robots to transfer hazardous oxidizer -- a type of propellant -- into the tanks of satellites in space today.

via Science Daily

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A small step toward discovering habitable Earths

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For the first time, astronomers have used the same imaging technology found in a digital camera to take a picture of a planet far from our solar system with an Earth-based telescope. The accomplishment is a small step toward the technology astronomers will need in order to characterize planets suitable for harboring life.

via Science Daily

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