SiliconTransistor
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IBM unlocks the secret to carbon nanotube transistors
Following Moore's law is getting harder and harder, especially as existing components reach their physical size limitations. Parts like silicon transistor contacts -- the "valves" within a transistor that allow electrons to flow -- simply can't be shrunken any further. However, IBM announced a major engineering achievement on Thursday that could revolutionize how computers operate: they've figured out how to swap out the silicon transistor contacts for smaller, more efficient, carbon nanotubes.
Researchers create working quantum bit in silicon, pave way for PCs of the future
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.
Nano vacuum tubes could give a second life to the guitarist's best friend
Pretty much the only place you see vacuum tubes any more is inside a quality audio amp. But, once upon a time, they were the primary ingredient in any piece of electronic equipment, including computers. The glass tubes have since been replaced with the smaller, less fragile and cheaper to manufacture silicon transistor. There are, however, disadvantages, to transistors. For one, electrons tend to move more slowly though the semiconductors, and two, they're highly susceptible to radiation. The second of those problems doesn't affect us much here on Earth, but for NASA it poses a major obstacle. Engineers have finally managed to combine the advantages of both vacuum tubes and silicon transistors, though, in what has been dubbed "nano vacuum tubes." They're created by etching tiny cavities in phosphorous-doped silicon, bordered on three sides by electrodes that form the gate, source and drain. The term "vacuum tube" is slightly misleading however, since there is no true vacuum in play. Instead, the source and drain are separated by just 150 nanometers, making it highly unlikely that flowing electrons would run into stray atoms. In addition to their space-worthy hardiness, they can also potentially operate at frequencies ten-times as higher than silicon transistors, making them a candidate to push terahertz tech from experimental to mainstream. For more, check out the source link. [Image credit: Shane Gorski]
Researchers build optical transistor out of silicon, provide path to all-optical computing
The speed of light is the universal speed limit, so naturally, optical technologies appeal when trying to construct speedy computational devices. Fiber optics let us shoot data to and fro at top speed, but for the time being our CPUs still make their calculations using electronic transistors. Good news is, researchers from Purdue University have built an optical transistor out of silicon that can propagate logic signals -- meaning it can serve as an optical switch and push enough photons to drive two other transistors. It's constructed of a microring resonator situated next to one optical line that transmits the signal, and a second that heats the microring to change its resonant frequency. The microring then resonates at a specific frequency to interact with the light in the signal line in such a way that its output is drastically reduced and essentially shut off. Presto, an optical transistor is born. Before dreams of superfast photonic computers start dancing in your head, however, just know they won't be showing up anytime soon -- the power consumption of such transistors is far beyond their electronic counterparts due to the energy inefficient lasers that power them.
