A French and an American scientist won the Nobel Prize 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 behaviour that previously could only be imagined in
equations and thought experiments.
Wineland has 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 of Sciences, which awarded them the 8
million crown ($1.2 million) Nobel Prize in Physics.
"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
recognised 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
by telephone. "First I called my children, then I called my closest
colleagues, without whom I would never have won this prize," he said.
Asked how he would celebrate, he said: "I will have champagne, of
course.
"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".
Physics is the second of this year's crop of awards; scientists from
Britain and Japan shared the first prize on Monday, in medicine, for
adult stem cell research. The prizes, which reward achievements in
science, literature and peace, were first awarded in 1901 in accordance
with the will of Swedish dynamite millionaire Alfred Nobel.
WEIRDER ASPECTS
"This year's Nobel Prize recognises 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."
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 "parlor trick" was to hit an atom with laser light,
which according to quantum theory would have 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.
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