(Reuters) -
A French and an American scientist won the Nobel Prize in physics on Tuesday
for finding ways to measure quantum particles without destroying them, which
could make it possible to build a new kind of computer far more powerful than
any seen before.
Serge
Haroche of France and American David Wineland, both 68, found ways to
manipulate the very smallest particles of matter and light to observe strange
behavior that previously could only be imagined in equations and thought
experiments.
Wineland
once described his own work as a "parlour trick" that performed the
seemingly magical feat of putting an object in two places at once. Other
scientists praised the achievements as bringing to life the wildest dreams of
science fiction.
"The
Nobel laureates have opened the door to a new era of experimentation with
quantum physics by demonstrating the direct observation of individual quantum
particles without destroying them," said the Royal Swedish
Academy
"Perhaps
the quantum computer will change our everyday lives in this century in the same
radical way as the classical computer did in the last century."
Haroche said
he was walking in the street with his wife when he recognized the Swedish
country code on the incoming call to inform him of the award.
"I saw
the area code 46, then I sat down," he told reporters in Sweden
He told
Reuters he hoped the prize would give him a platform "that will allow me
to communicate ideas, not just in this field of research but for research in
general, fundamental research".
Wineland
was asleep at home in Boulder , Colorado ,
when the phone call from Stockholm
Physics is
the second of this year's crop of awards; scientists from Britain and Japan
"This
year's Nobel Prize recognizes some of the most incredible experimental tests of
the weirder aspects of quantum mechanics," said Jim Al-Khalili, professor
of physics at the University of Surrey in Britain
"Until
the last decade or two, some of these results were nothing more than ideas in
science fiction or, at best, the wilder imaginations of quantum physicists.
Wineland and Haroche and their teams have shown just how strange the quantum
world really is and opened up the potential for new technologies undreamt of
not so long ago."
INGENIOUS
METHODS
Quantum
physics studies the behavior of the fundamental building blocks of the universe
at a scale smaller than atoms, when tiny particles act in strange ways that can
only be described with advanced mathematics.
Researchers
have long dreamt of building "quantum computers" that would operate
using that mathematics - able to conduct far more complicated calculations and
hold vastly more data than classical computers. But they could only be built if
the behavior of individual particles could be observed.
"Single
particles are not easily isolated from their surrounding environment, and they
lose their mysterious quantum properties as soon as they interact with the
outside world," the Nobel committee explained.
"Through
their ingenious laboratory methods Haroche and Wineland, together with their
research groups, have managed to measure and control very fragile quantum
states, which were previously thought inaccessible for direct observation. The
new methods allow them to examine, control and count the particles."
Both
scientists work in the field of quantum optics, studying the fundamental
interactions between light and matter. The Nobel committee said they used
opposite approaches to the same problem: Wineland uses light particles - or
photons - to measure and control particles of matter - electrons - while
Haroche uses electrons to control and measure photons.
In one of
the strange properties of quantum mechanics, tiny particles act as if they are
simultaneously in two locations, based on the likelihood that they would be
found at either, known as a "superposition."
It was long
thought that it would be impossible to demonstrate this in a lab. But
Wineland's "parlour trick" was to hit an atom with laser light, which
according to quantum theory had a 50 percent chance of moving it, and observe
the atom at two different locations, 80 billionths of a meter apart.
In a normal
computer, a switch must either be on or off. A quantum computer would work with
switches that, like the particles in Wineland's experiment, behaved as if they
were in more than one position at the same time.
An example
is a computer trying to work out the shortest route around town for a
travelling salesman. A traditional computer might try every possible route and
then choose the shortest. A quantum computer could do the calculation in one
step, as if the salesman travelled each route simultaneously.
Wineland is
a dedicated experimentalist, not bothered by the bizarre philosophical
implications of quantum mechanics, such as the notion that reality does not
exist until an observer measures it. "You can find debate on this, but I'm
not sure we're so special in the universe" as to have the power to bring
reality into being, he told Reuters.
His realism
extends to applications of his work. "I wouldn't recommend anybody buy
stock in a quantum computing company," Wineland told reporters, but he
said he was optimistic that it might be possible to build one eventually.
He plans to
be part of the quest. Asked if his science career was nearing an end, he said
he had no plans to retire "until they drag me out of here for being too
old".
($1 = 6.6125 Swedish crowns)
(Additional
reporting by Sharon Begley, Patrick Lannin, Alistair Scrutton, Chris Wickham,
Ben Hirschler, Nicholas Vinocur and Keith Coffman; Writing by Peter Graff;
Editing by Will Waterman and Pravin Char)
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