快猫短视频

All tied up

Entangling particles is easy when you know how

THE dream of teleporting atoms and molecules鈥攁nd maybe even larger
objects鈥攈as become a real possibility for the first time. The advance is
thanks to physicists who have suggested a method that in theory could be used to
鈥渆ntangle鈥 absolutely any kind of particle.

Quantum entanglement is the bizarre property that allows two particles to
behave as one, no matter how far apart they are. If you measure the state of one
particle, you instantly determine the state of the other. This could one day
allow us to teleport objects by transferring their properties instantly from one
place to another. Until now, physicists have only been able to entangle photons,
electrons and atoms, using different methods in each case. For instance, atoms
are entangled by forcing them to interact inside an optical trap, while photons
are made to interact with a crystal.

鈥淭hese schemes are very specific,鈥 says Sougato Bose of the University of
Oxford. But Bose and Dipankar Home, of the Bose Institute in Calcutta, have now
demonstrated a single mechanism that could be used to entangle any particles,
even atoms or large molecules.

To see how it works, consider the angular momentum or 鈥渟pin鈥 of an electron.
To entangle the spins of two electrons, you first need to make sure they鈥檙e
identical in all respects but their spin. Then you shoot the electrons
simultaneously into a beam splitter. This device 鈥渟plits鈥 each electron into a
quantum state called a superposition, which gives it an equal probability of
travelling down either of two paths. Only when you try to detect the electron do
you know which path it took. If you split two electrons simultaneously, both
paths could have one electron each (which will happen half of the time) or
either path could have both.

Bose and Home show mathematically that whenever one electron is detected in
each path, they will be entangled. While a similar effect has been demonstrated
before for photons, the photons used were already entangled in another way, even
before they reached the beam splitter. 鈥淥ne of the advances we have made is that
these two particles could be from completely independent sources,鈥 says
Bose.

The technique should work for any objects鈥攁toms, molecules and who
knows what else鈥攁s long as you can split the beam into a quantum
superposition. Anton Zeilinger, a quantum physicist at the University of Vienna
in Austria, has already shown that this quantum state is possible with
buckyballs鈥攆ootball-shaped molecules of C60. Although entangling
such large objects is beyond our technical abilities at the moment, this is the
first technique that might one day make it possible.

Any scheme that expands the range of particles that can be entangled is
important, says Zeilinger. Entangling massive particles would mean they could
then be used for quantum cryptography, computing and even teleportation. 鈥淚t
would be fascinating,鈥 he says. 鈥淭he possibility that you can teleport not just
quantum states of photons, but also of more massive particles, that in itself is
an interesting goal.鈥

  • More at:
    Physical Review Letters (vol 88, article 05401)

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