Hasta La Gadget!

If you’ve been paying attention, you know the quantum computing revolution is coming — and so far the world has a mini quantum network, not to mention the $10,000 D-Wave One, to show for it. Researchers from the University of Melbourne and University College, London, have now developed the “first working quantum bit based on a single atom of silicon.” By measuring and manipulating the magnetic orientation, or spin, of an electron bound to a phosphorus atom embedded in a silicon chip, the scientists were able to both read and write information, forming a qubit, the basic unit of data for quantum computing.

The team used a silicon transistor, which detects the electron’s spin and captures its energy when the spin’s direction is “up.” Once the electron is in the transistor, scientists can change its spin state any way they choose, effectively “writing” information and giving them control of the quantum bit. The next step will be combing two qubits into a logic step, with the ultimate goal being a full-fledged quantum computer capable of crunching numbers, cracking encryption codes and modeling molecules that would put even supercomputers to shame. But, you know, baby steps.

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Researchers create working quantum bit in silicon, pave way for PCs of the future originally appeared on Engadget on Fri, 21 Sep 2012 00:47:00 EDT. Please see our terms for use of feeds.

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A fundamental challenge of developing spintronics, or computing where the rotation of electrons carries instructions and other data rather than the charge, has been getting the electrons to spin for long enough to shuttle data to its destination in the first place. IBM and ETH Zurich claim to be the first achieving that feat by getting the electrons to dance to the same tune. Basing a semiconductor material on gallium arsenide and bringing the temperature to an extremely low -387F, the research duo have created a persistent spin helix that keeps the spin going for the 1.1 nanoseconds it would take a normal 1GHz processor to run through its full cycle, or 30 times longer than before. As impressive as it can be to stretch atomic physics that far, just remember that the theory is some distance from practice: unless you’re really keen on running a computer at temperatures just a few hops away from absolute zero, there’s work to be done on producing transistors (let alone processors) that safely run in the climate of the family den. Assuming that’s within the realm of possibility, though, we could eventually see computers that wring much more performance per watt out of one of the most basic elements of nature.

Continue reading IBM creates consistent electron spin inside semiconductors, takes spintronics one twirl closer

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IBM creates consistent electron spin inside semiconductors, takes spintronics one twirl closer originally appeared on Engadget on Mon, 13 Aug 2012 14:41:00 EDT. Please see our terms for use of feeds.

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Electron microscopes can produce incredibly detailed and even 3D views of sub-cellular structures, but often at the cost of losing the bigger picture. Researchers at Leiden University in the Netherlands, however, have leveraged a technique called virtual nanoscopy that enables researchers to observe the whole of a cell and its intricate details in a single image. With the method, the team stitches together nanometer resolution photographs of what’s gone under the scope to create a map with adjustable zoom a la Google Maps. Their study created a 281-gigapixel image (packed with 16 million pixels per inch) of a 1.5-millimeter-long zebrafish embryo. If you’d like to take a gander at the ultra-high resolution fish or read up on the group’s findings for yourself, check out the source links below.

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Scientists generate 281-gigapixel cell map using electron microscope originally appeared on Engadget on Wed, 08 Aug 2012 04:32:00 EDT. Please see our terms for use of feeds.

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