2010-09-17, 03:20 AM
I just love seeing the word 'quantum' when talking about computers.
http://www.ft.com/cm...144feab49a.html
A new photonic chip that works on light rather than electricity has been built by an international research team, paving the way for the production of ultra-fast quantum computers with capabilities far beyond todayâs devices.Future quantum computers will, for example, be able to pull important information out of the biggest databases almost instantaneously. As the amount of electronic data stored worldwide grows exponentially, the technology will make it easier for people to search with precision for what they want.
An early application will be to investigate and design complex molecules, such as new drugs and other materials, that cannot be simulated with ordinary computers. More general consumer applications should follow.
Jeremy OâBrien, director of the UKâs Centre for Quantum Photonics, who led the project, said many people in the field had believed a functional quantum computer would not be a reality for at least 25 years.
âHowever, we can say with real confidence that, using our new technique, a quantum computer could, within five years, be performing calculations that are outside the capabilities of conventional computers,â he told the British Science Festival, as he presented the research.
Computingâs great leap forward
Why quantum computing?
To make use of properties that emerge on an ultra-small scale. âEntanglementâ â the ability of subatomic particles to influence one another at a distance â and âsuperpositionâ â the fact that a particle does not have a definite location and can be in several places at once â are the two most important properties.
Yes, itâs weird but why is it useful?
Because quantum particles can do very many things at the same time, unlike an electronic âbitâ in conventional computing. The use of quantum particles, or âqubitsâ, permits parallel computing on a scale that would not be possible with conventional electronics.
What particles are you talking about?
Many scientists are working with atoms or ions trapped in ultra-cold conditions. But the latest discovery by the Bristol-led team uses photons â light particles.
How does a quantum chip actually work?
There are several models. The Bristol version sends âentangledâ photons down networks of circuits in a silicon chip. The particles perform a co-ordinated âquantum walkâ, whose outcome represents the results of a calculation. <br align="block">Of course, special software and input-output devices will have to be developed <br align="block">to make practical use of the device.
The breakthrough, published today in the journal Science, means data can be processed according to the counterintuitive rules of quantum physics that allow individual subatomic particles to be in several places at the same time.
This property will enable quantum computers to process information in quantities and at speeds far beyond conventional supercomputers. But formidable technical barriers must be *overcome before quantum *computing becomes practical.
The team, from Bristol university in the UK, Tohuku university in Japan, Weizmann Institute in Israel and Twente university in the Netherlands, say they have overcome an important barrier, by making a quantum chip that can work at ordinary temperatures and pressures, rather than the extreme conditions required by other approaches.
The immense promise of quantum computing has led governments and companies worldwide to invest hundreds of millions of dollars in the field.
Big spenders, including the US defence and intelligence agencies concerned with the national security issues, and governments â such as Canada, Australia and Singapore â see quantum electronics as the foundation for IT industries in the mid-21st century.
Copyright The Financial Times Limited 2010. You may share using our article tools. Please don't cut articles from FT.com and redistribute by email or post to the web.
http://www.ft.com/cm...144feab49a.html
A new photonic chip that works on light rather than electricity has been built by an international research team, paving the way for the production of ultra-fast quantum computers with capabilities far beyond todayâs devices.Future quantum computers will, for example, be able to pull important information out of the biggest databases almost instantaneously. As the amount of electronic data stored worldwide grows exponentially, the technology will make it easier for people to search with precision for what they want.
An early application will be to investigate and design complex molecules, such as new drugs and other materials, that cannot be simulated with ordinary computers. More general consumer applications should follow.
Jeremy OâBrien, director of the UKâs Centre for Quantum Photonics, who led the project, said many people in the field had believed a functional quantum computer would not be a reality for at least 25 years.
âHowever, we can say with real confidence that, using our new technique, a quantum computer could, within five years, be performing calculations that are outside the capabilities of conventional computers,â he told the British Science Festival, as he presented the research.
Computingâs great leap forward
Why quantum computing?
To make use of properties that emerge on an ultra-small scale. âEntanglementâ â the ability of subatomic particles to influence one another at a distance â and âsuperpositionâ â the fact that a particle does not have a definite location and can be in several places at once â are the two most important properties.
Yes, itâs weird but why is it useful?
Because quantum particles can do very many things at the same time, unlike an electronic âbitâ in conventional computing. The use of quantum particles, or âqubitsâ, permits parallel computing on a scale that would not be possible with conventional electronics.
What particles are you talking about?
Many scientists are working with atoms or ions trapped in ultra-cold conditions. But the latest discovery by the Bristol-led team uses photons â light particles.
How does a quantum chip actually work?
There are several models. The Bristol version sends âentangledâ photons down networks of circuits in a silicon chip. The particles perform a co-ordinated âquantum walkâ, whose outcome represents the results of a calculation. <br align="block">Of course, special software and input-output devices will have to be developed <br align="block">to make practical use of the device.
The breakthrough, published today in the journal Science, means data can be processed according to the counterintuitive rules of quantum physics that allow individual subatomic particles to be in several places at the same time.
This property will enable quantum computers to process information in quantities and at speeds far beyond conventional supercomputers. But formidable technical barriers must be *overcome before quantum *computing becomes practical.
The team, from Bristol university in the UK, Tohuku university in Japan, Weizmann Institute in Israel and Twente university in the Netherlands, say they have overcome an important barrier, by making a quantum chip that can work at ordinary temperatures and pressures, rather than the extreme conditions required by other approaches.
The immense promise of quantum computing has led governments and companies worldwide to invest hundreds of millions of dollars in the field.
Big spenders, including the US defence and intelligence agencies concerned with the national security issues, and governments â such as Canada, Australia and Singapore â see quantum electronics as the foundation for IT industries in the mid-21st century.
Copyright The Financial Times Limited 2010. You may share using our article tools. Please don't cut articles from FT.com and redistribute by email or post to the web.
Paul
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