Faster Computers With Nanotechnology

The silicon transistors in computers may be replaced in ten years by transistors based on carbon nanotubes. The scientists at the University of Gothenburg have developed a method to control the nanotubes during production.
Silicon is subject to certain limitations, and industry is looking for a replacement. Carbon nanotubes can be used to produce smaller and faster components. This will also result in computers that consume less energy.

The amazing development in computer power that has taken place after the invention of the integrated circuit in the 1950s has been made possible by the transistor, which is the most important component of all processors, becoming ever-faster.

The most common semiconductor material in transistors is silicon, since it is cheap and easy to process. But silicon has its limitations. As the size of the transistors is reduced in order to increase their speed, problems arise that lead to, among other things, increased energy consumption and large variation in the transistor properties.

By exchanging the silicon in the channel for a carbon nanotube, the transistors can be made both smaller and faster than today’s transistors. A carbon nanotube is a molecule in form of a hollow cylinder with a diameter of around a nanometer (roughly 1/50,000 of the width of a human hair) which consists of pure carbon. Some carbon nanotubes are semiconducting, and this means that they can be used in transistors, although there are several problems that must be solved before they can be connected together to form large circuits.

Carbon nanotubes grow randomly and it is not possible to control either their position or direction. Therefore an electrical field is applied to guide the tubes as they grow. One of the effects of the electric field is that most of the carbon nanotubes lie in the same direction.

Another problem that must be solved when integrating nanotubes into larger circuits is the difficulty of manufacturing good metal contacts for the tubes. Research has shown that the properties of the contacts depend on the diameter of the nanotubes. Choosing the correct diameter will allow good contacts with a low resistance to be achieved.

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