Silicon is dead. Long live, carbon nanotubes.
In transistors, size matters — a lot. You can’t squeeze more silicon transistors (think billions of them) into a processor unless you can make them smaller, but the smaller these transistors get, the higher the resistance between contacts, which means the current can’t flow freely through them and, in essence, the transistors and chips built based on them, can no longer do their jobs. Ultra-tiny carbon nanotube transistors, though are poised to solve the size issue.
In a paper published on Thursday in the journal Science, IBM scientists announced they had found a way to reduce the contact length of carbon nanotube transistors — a key component of the tech and the one that most impacts resistance — down to 9 nanometers without increasing resistance at all. To put this in perspective, contact length on traditional, silicon-based 14nm node technology (something akin to Intel’s 14nm technology) currently sits at about 25 nanometers.
“In the silicon space, the contact resistance is very low if the contact is very long. If contact is very short, the resistance shoots up very quickly and gets large. So you have trouble getting current through the device,” Wilfried Haensch, IBM Senior Manager, Physics & Materials for Logic and Communications, told me.
… carbon nanotubes, which happen to be 10,000 times thinner than a single strand of human hair, have been a promising tech for continuing Moore’s Law
Because of their unique properties, carbon nanotubes, which happen to be 10,000 times thinner than a single strand of human hair, have been a promising tech for continuing Moore’s Law carbon nanotubes, which happen to be 10,000 times thinner than a single strand of human hair, have been a promising tech for continuing Moore’s Law, which roughly states that the number of transistors in an integrated circuit will double every two years. However, according to Haensch, the technology faces considerable hurdles before it can be considered appropriate for commercial integrated circuit development.
First of all, the creation of tubes you can use in semiconductors isn’t easy. Haensch told me the current yields for useful material are still well below what they need. They also have to work out how to place the nanotubes 10nm apart or less on a wafer. Thirdly, they have to be able to scale devices based on carbon nanotubes to competitive dimensions.
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