Researchers from Imperial College London, Durham University and the University of Sheffield say their new computer chip design will enable large amounts of data to be stored in small volumes by using a complex interconnected network of nanowires, with computing functions and decisions performed at the nodes where they meet – a similar approach to neurons and axons in the brain.
Currently the memory chips of mobile phones have a very limited capacity, making it impossible to store the videos that the new generation of phones can record. Electronics firms have been looking at miniature hard drive disks as a possible solution but so far the high expense of this option has rendered it unattractive.
This latest research, however, has the potential to develop a chip that combines the storage capability of a hard drive with the low cost of memory cards, potentially increasing memory capacity by 200 times from an average of 500MB to around 100GB.
Lead researcher Russell Cowburn, Professor of Nanotechnology in Imperial's Department of Physics, explains: "The new video mobile phones are very popular, but they desperately need more memory so that people can take longer videos and store them. This technology has the potential to transform mobiles into fully functioning video cameras, in addition to a range of other applications."
The technology is based on the discovery by Professor Cowburn and colleagues that by using nanotechnology it is possible to reproduce the key functions of semiconductor electronics in microchips using only the 'spin' of electrons, which is responsible for magnetism, rather than the more conventional 'charge' that traditional microchips use.
This has allowed them to construct a completely new architecture for electronics in three dimensions rather than the two dimensional flat structure of conventional microchips, an approach Professor Cowburn compares to using cupboards instead of table tops for storing goods. He says:
"Traditionally we have used electronics for microchips and magnetism for hard disk drives. This discovery allows us to combine these two approaches to make a new generation of 3D microchips that can store so much more information than a flat two dimensional surface. "
The team is now working with commercial partners to develop the technology and is currently building a more advanced demonstrator chip using full microchip manufacturing facilities.
Notes to Editors:
Magnetic Domain-Wall Logic, Science, Volume 310, 9 September 2005
D A Allwood1, G Xiong2, C C Faulkner3, D Atkinson2, D Petit3, R P Cowburn3, 4
1 Department of Engineering Materials, University of Sheffield
2 Department of Physics, University of Durham
3 Department of Physics, Imperial College London
4 Durham Magnetic Optics Ltd, University of Durham
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