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Quantum Progress?

Published online: 21 July 2005 on nature.com
Quantum computers go for a spin
Philip Ball



A quantum computer would make a conventional supercomputer look like a Palm Pilot.

Two physicists have come up with an idea that could crack the as yet unsolved problem of how to build a quantum computer, a device that would make a conventional supercomputer look like a Palm Pilot.

Hans-Andreas Engel and Daniel Loss of the University of Basel in Switzerland have explained how to make a device called a spin-parity meter.

Such an invention would be analogous to the transistors in microchips: a kind of universal component for building quantum-computer circuitry, says theorist David DiVincenzo of IBM's research labs in Yorktown Heights, New York. The imagined component could allow electronic quantum computers to be made from silicon, just as today's microprocessor chips are.

"With a spin-parity meter in hand, quantum computing could be just around the corner," says physicist José Carlos Egues of the University of São Paulo in Brazil.

But at the moment, Engel and Loss's idea is just that: an idea. They have worked out how a spin-parity meter could be put together in principle, and their theoretical calculations show that it could function as a component of a quantum computer. But they haven't made a real device.

In an electronic quantum computer, information would be encoded in the magnetic state or 'spins' of electrons: 'up' and 'down' spins would substitute for the ones and zeros of binary code in conventional computers.

Because of the wave nature of quantum particles, pairs of electrons can exist not only as discrete pairs of up and down spins but also as mixtures of such combinations, where each electron can be considered to have an up and down spin simultaneously.

This allows a quantum computer access to many more information-encoding states than a conventional computer, and so it can perform some calculations much more quickly and efficiently.

Last year DiVincenzo and his co-workers theorized about an electronic quantum computer that avoided some of the complications of previous proposals2. In their scheme, computing is performed not by feeding data into one end of a circuit and looking at how it emerges at the other end, but by looking at the pattern the data makes as it spreads out through a network of components, just as ripples spread from a pebble dropped in water.

To do this one would need to measure the 'parity' of electron pairs (whether their spins are aligned or opposite) without disturbing them. This is what Engel and Loss have now shown how to do.

Quantum jump
Engel and Loss describe a system in which a pair of electrons is placed in a tiny blob of semiconducting material such as silicon, called a quantum dot. There is a second, empty quantum dot nearby. By applying a magnetic field, it is possible to 'tune' the system such that the energy of neighbouring dots is the same if and only if they contain a pair of electrons with opposite spin. This energy equality allows those electrons with opposing spins to jump between quantum dots. Such jumps can be detected by a highly sensitive meter for measuring electrical charge, and the opposing spins of the electrons can therefore be inferred.

Their scheme, says DiVincenzo, is "a little bit of a mindbender" that could change they way others think about how to make quantum computers. "Experimentalists really pay attention to these people," he says.

Egues says that the "breathtaking" experimental advances that have taken place recently in the relevant electronic technologies "definitely pave the way to an actual implementation" of the idea.

References
Engel H. A., Loss D., et al. Science, 309. 586 - 588 (2005).
Beenakker C. W. J., et al. Phys. Rev. Lett, 93. 020501 (2004). | Article | PubMed | ChemPort |

Comments

delascabezas
Jul. 22nd, 2005 02:09 pm (UTC)
sweet, i definitely want to check that out
i think it is funny how math and nature have reversed their relationship since the age of exberance. there used to be a cosmic order and harmony, and now the only cosmic "order" seems to be in the patterns of discorndance and disharmony created through applied chaos.

theoretical quantum computing, hell, quantum mechanics has totally changed my day-to-day life (in terms of outlook). my brain chills at the thought of those theories applied, and how that might change things.
rhodamine
Jul. 22nd, 2005 02:15 pm (UTC)
Re: sweet, i definitely want to check that out
i tend to think that what we call "chaos" is actually immense periodic functions... that is, patterns either too huge or too small for us to even comprehend... yet.

hi, youve stumbled onto one of my pet topics! :D :D if youre ever hungry for some mildly analytic-but-still-amusing texts on this subject, we should do a book trade...

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delascabezas
The Son of the last of a long line of thinkers.
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