Product category:
Contract research
News Release from: STFC Daresbury Laboratory | Subject: Daresbury Laboratory
Edited by the Laboratorytalk Editorial
Team on 17 April 2008
Miniaturising electronics to the
nanoscale
As the demand for the miniaturisation of gadgets meets with the quest for infinitely larger memories, the critical limitations are those posed by the traditional silicon chip
An MP3 player with a one million gigabyte memory capacity could soon be a reality A team of scientists led by the University of Glasgow, working alongside colleagues at the STFC Daresbury Laboratory in Warrington, have successfully created a new type of molecular device that has the potential to dramatically increase the storage capacity in electronic devices
This article was originally published on Laboratorytalk on 17 Mar 2008 at 8.00am (UK)
Related stories
X-rays shed light on magnetic bacteria
Daresbury Laboratory's synchrotron creates highly polarised X-rays to examine bio-nanomagnetic bacteria dosed with cobalt to change in their magnetic properties
Synchrotron sheds light on cancer diagnosis
CLRC Daresbury's Synchrotron Radiation Department has provided details of its groundbreaking use of scattered x-rays for breast cancer screening, reducing the need for biopsies
Funding for groundbreaking materials research
National Centre for Electron Spectroscopy and Surface Analysis granted EPSRC funds to upgrade world-class facility for X-ray photoelectron spectroscopy
The full paper on this research has been published (30 March) in the scientific publication Nature Nanotechnology.
Using X-rays at the Daresbury Laboratory's synchrotron light source (SRS), this team of scientists have formed a totally new type of molecular switch using nanoparticles, paving the way for a new generation of devices and applications.
The switching ability is controlled by taking these nanoparticles, a millionth of a millimetre in size, and placing them onto a gold or carbon surface, bridging the gap between traditional semi-conductor based devices and components for nanoscale plastic electronics.
This facilitates a move away from silicon towards carbon-based electronics, which are much easier to manipulate and more flexible both physically and technologically.
The key advantage of this molecule-size switch is information storage and the increased transistor density compared to that of traditional semi-conductors.
For example, this molecule size switch would lead to an increase in data storage to a million gigabytes per square inch, an increase on current memory capabilities of around 150,000 times.
If the switch was used to form molecular- based transistors then the number of transistors per chip could grow from today's 200 million to over one billion per chip.
The research shows conceptually that this huge gain in nanoscale electronics is possible.
By building transistors from molecules, the idea is to build devices from the bottom up, making them easier to build and manipulate.
This means that the smallest mobile phone could have the equivalent memory of the most powerful personal computer Vin Dhanak, a research scientist at Daresbury Laboratory said:"This research shows that the potential is there for your future iPod to have hundreds of thousands times more capacity to store music and video than currently possible".
"As in the case with other molecular based devices, such as carbon nanotubes, the challenge we are faced with now is in resolving fabrication issues.".
• STFC Daresbury Laboratory: contact details and other news
• Email this article to a colleague
• Register for the free Laboratorytalk email newsletter
• Laboratorytalk Home Page
Search the Pro-Talk network of sites
