In a report published in Nature magazine, Stanford doctoral student Max Shulaker and his fellow students, Gage Hills, Nishant Patil, Hai Wei and Hong-Yu Chen, along with Stanford professors Subhasish Mitra and H.S. Philip Wong, describe their work.
Carbon nanotubes are, as their name suggests, nanoscale tubes made of the element carbon. A nanometer (nm) is 1 billionth of a meter, and about 10,000 times thinner than a human hair. Nanotubes themselves come in varying diameters, from less than 1 nm to about 50 nm. Their lengths have tended toward thousands of nanometers, or microns, though recent advances have extended nanotube measurements into the centimeter range.
They are all exceedingly small and difficult to work with. The Stanford researchers' achievement involved developing a manufacturing process that can eliminate defective and misaligned nanotubes without having to look for them. In essence, they created an automated way to find tiny needles in very, very small haystacks.
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The computer that the researchers designed is rudimentary. It's intended as a proof-of-concept rather than a production model. Nevertheless, it is "Turing Complete," meaning it is a system that can run arbitrary code and solve any computational problem, given enough time.
It uses 178 transistors, each of which contains between 10 and 200 carbon nanotubes. It can perform four basic operations that allow it to do things like count and sort numbers. It can run two programs at the same time.
An actual commercial computer based on carbon nanotubes is still many years away. It took a decade and a half to move from the first nanotube transistors to a prototype nanotube computer.
The reason this matters is that scientists doubt they can continue to increase transistor density in silicon semiconductor chips for much longer. As engineers have successfully made successive generations of silicon chips smaller and more tightly packed — a trend predicted in 1965 by Intel cofounder Gordon Moore and now referred to as Moore's Law — heat dissipation has become more of an issue. Barring further chip design breakthroughs, we will soon reach a point where traditional silicon-based semiconductors just won't be able to be made any smaller.
That's where carbon nanotubes come in. According to Wong, nanotubes could take us "an order of magnitude" beyond where silicon chips can go. What's more, carbon nanotubes and silicon transistors can work together on the same chip, which suggests the possibility of a hybrid transition path.