NOTHING sits still. Even at absolute zero, when the
thermal jiggling of matter is frozen, all things must still buzz to the
tune of quantum mechanics. Now this subtle jittering has been detected
in a small silicon bar, the first solid object ever to reveal its
quantum vibrations.
This
phenomenon, called zero-point fluctuation, is a consequence of
Heisenberg's uncertainty principle, which says that we can never pin
down the precise position and motion of any object. So far zero-point
energy has only been seen directly in single atoms or small collections
of particles.
The new experiment uses a silicon bar about 12 micrometres long and less than a micrometre across. Oskar Painter
at the California Institute of Technology in Pasadena and colleagues
cooled the bar to within half a degree of absolute zero and then used a
laser to detect its motion.
Some
photons from this laser got a shift in energy when they hit the
vibrating bar. Ordinary thermal vibrations can either boost or reduce
photon energy, but the zero-point quantum vibration is different.
Because it is the lowest energy state possible, it can only absorb
energy. Painter's group detected this bias towards lower-energy
scattered light, a clear signature of a quantum twang (Physical Review Letters, DOI: 10.1103/physrevlett.108.033602).
"Seeing
these effects in large objects can provide us with a way to probe the
foundations of quantum mechanics," says Caltech team member Amir
Safavi-Naeini.
http://www.newscientist.com/
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