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Nanowires may allow many more transistors to be placed on computer chips in the future

Engineers and researchers predict that in the next five to ten years the dimensions of silicon transistors will have been scaled to their limits and will be unable to get any smaller. Without a new breakthrough in creating smaller transistors, Moore's Law will fall flat.

A group of engineers and researchers working together from IBM, Purdue University, and the University of California at Los Angles has learned to create nanowires coated with materials that make for efficient transistors. The nanowires have very sharply defined layers at the atomic level that allow the wires to be efficient transistors.

Eric Stach, associate professor of materials Engineering from Purdue said, "Having sharply defined layers of materials enables you to improve and control the flow of electrons and to switch this flow on and off."

The team of researchers says that electronic devices are often constructed of heterostructures. The term heterostructures means that the structure contains sharply defined layers of different semiconducting materials like silicon and germanium. According to the researchers, the challenge in the past has been the capability of producing nanowires with the requisite defined layers.

The team has detailed its findings in a paper published in the November 27 edition of the journal Science. The transistors that the team have developed are not made on flat pieces of silicon. These nanowires are grown vertically making them have a much smaller footprint, which in turn allows for many more of the nanowires to be placed on the same piece of silicon.

Stach said, "But first we need to learn how to manufacture nanowires to exacting standards before industry can start using them to produce transistors."

The researchers used a transmission electron microscope to view the nanowire formation. The nanowires were formed by heating tiny particles of a gold-aluminum alloy in a vacuum chamber. After the alloy was melted the researchers introduced silicon gas and the alloy bead absorbed the gas becoming supersaturated with silicon. This caused a silicon wire to grow from the alloy bead producing a silicon wire that was topped with a mushroom-like gold-aluminum alloy bead.

At that point, the researchers reduced the temperature of the chamber enough to allow the alloy bead at the top of the wire to solidify, thereby allowing germanium to be deposited on the silicon precisely creating the required heterostructure needed to create a transistor. The heterostructure allows the formation of a germanium gate in each transistor allowing devices to switch on and off.

"The cycle could be repeated, switching the gases from germanium to silicon as desired to make specific types of heterostructures," Stach said.



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By hyvonen on 11/30/2009 7:32:14 AM , Rating: 2
quote:
...fell out of development effort because of Silicon's abundance and affordability.


And that's the key. Research on other options is being done in universities and corporate research labs, but a total overhaul of process technology is a tad expensive - as long as bulk silicon can be "tweaked" (strain, HKMG etc.) economically to enable continued scaling of size, cost and performance, that's what companies will do.


“So far we have not seen a single Android device that does not infringe on our patents." -- Microsoft General Counsel Brad Smith











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