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Trying to explain quantum “spooky action at a distance” using any kind of signal pits Einstein’s relativity against our concept of a smooth spacetime. Credit: Timothy Yeo / CQT, National University of Singapore |
Physicists have proposed an experiment
that could force us to make a choice between extremes to describe the
behaviour of the Universe.
The proposal comes from an
international team of researchers from Switzerland, Belgium, Spain
and Singapore, and is published today in Nature Physics. It is based
on what the researchers call a 'hidden influence inequality'. This
exposes how quantum predictions challenge our best understanding
about the nature of space and time, Einstein's theory of relativity.
"We are interested in whether we
can explain the funky phenomena we observe without sacrificing our
sense of things happening smoothly in space and time," says
Jean-Daniel Bancal, one of the researchers behind the new result, who
carried out the research at the University of Geneva in Switzerland.
He is now at the Centre for Quantum Technologies at the National
University of Singapore.
Excitingly, there is a real prospect of
performing this test.
The implications of quantum theory have
been troubling physicists since the theory was invented in the early
20th Century. The problem is that quantum theory predicts bizarre
behaviour for particles – such as two 'entangled' particles
behaving as one even when far apart. This seems to violate our sense
of cause and effect in space and time. Physicists call such behaviour
'nonlocal'.
It was Einstein who first drew
attention to the worrying implications of what he termed the "spooky
action at a distance" predicted by quantum mechanics. Measure
one in a pair of entangled atoms to have its magnetic 'spin' pointing
up, for example, and quantum physics says the other can immediately
be found pointing in the opposite direction, wherever it is and even
when one could not predict beforehand which particle would do what.
Common sense tells us that any such coordinated behaviour must result
from one of two arrangements. First, it could be arranged in advance.
The second option is that it could be synchronised by some signal
sent between the particles.
In the 1960s, John Bell came up with
the first test to see whether entangled particles followed common
sense. Specifically, a test of a 'Bell inequality' checks whether two
particles' behaviour could have been based on prior arrangements. If
measurements violate the inequality, pairs of particles are doing
what quantum theory says: acting without any 'local hidden variables'
directing their fate. Starting in the 1980s, experiments have found
violations of Bell inequalities time and time again.
Quantum theory was the winner, it
seemed. However, conventional tests of Bell inequalities can never
completely kill hope of a common sense story involving signals that
don't flout the principles of relativity. That's why the researchers
set out to devise a new inequality that would probe the role of
signals directly.
Experiments have already shown that if
you want to invoke signals to explain things, the signals would have
to be travelling faster than light – more than 10,000 times the
speed of light, in fact. To those who know that Einstein's relativity
sets the speed of light as a universal speed limit, the idea of
signals travelling 10,000 times as fast as light already sets alarm
bells ringing. However, physicists have a getout: such signals might
stay as 'hidden influences' – useable for nothing, and thus not
violating relativity. Only if the signals can be harnessed for
faster-than-light communication do they openly contradict relativity.
The new hidden influence inequality
shows that the getout won't work when it comes to quantum
predictions. To derive their inequality, which sets up a measurement
of entanglement between four particles, the researchers considered
what behaviours are possible for four particles that are connected by
influences that stay hidden and that travel at some arbitrary finite
speed.
Mathematically (and mind-bogglingly),
these constraints define an 80-dimensional object. The testable
hidden influence inequality is the boundary of the shadow this
80-dimensional shape casts in 44 dimensions. The researchers showed
that quantum predictions can lie outside this boundary, which means
they are going against one of the assumptions. Outside the boundary,
either the influences can't stay hidden, or they must have infinite
speed.
Experimental groups can already
entangle four particles, so a test is feasible in the near future
(though the precision of experiments will need to improve to make the
difference measurable). Such a test will boil down to measuring a
single number. In a Universe following the standard relativistic laws
we are used to, 7 is the limit. If nature behaves as quantum physics
predicts, the result can go up to 7.3.
So if the result is greater than 7 –
in other words, if the quantum nature of the world is confirmed –
what will it mean?
Here, there are two choices. On the one
hand, there is the option to defy relativity and 'unhide' the
influences, which means accepting faster-than-light communication.
Relativity is a successful theory that researchers would not call
into question lightly, so for many physicists this is seen as the
most extreme possibility.
The remaining option is to accept that
influences must be infinitely fast – or that there exists some
process that has an equivalent effect when viewed in our spacetime.
The current test couldn't distinguish. Either way, it would mean that
the Universe is fundamentally nonlocal, in the sense that every bit
of the Universe can be connected to any other bit anywhere,
instantly. That such connections are possible defies our everyday
intuition and represents another extreme solution, but arguably
preferable to faster-than-light communication.
"Our result gives weight to the
idea that quantum correlations somehow arise from outside spacetime,
in the sense that no story in space and time can describe them,"
says Nicolas Gisin, Professor at the University of Geneva,
Switzerland, and member of the team.
The researchers that carried out the
work, in addition to Dr Bancal and Prof Gisin, are Dr Stefano Pironio
from the Free University of Bruxelles in Belgium, Professor Antonio
Acín from the Institute of Photonic Sciences (ICFO) in Barcelona, Dr
Yeong-Cherng Liang from the University of Geneva, and Professor
Valerio Scarani from the Centre for Quantum Technologies and the
Department of Physics of the National University of Singapore.
Reference: J.-D. Bancal et al, Quantum
nonlocality based on finite-speed causal influences leads to
superluminal signalling", Nature Physics, DOI:10.1038/NPHYS2460
(2012).
Researcher Contacts
Dr Jean-Daniel Bancal
Centre for Quantum Technologies, National University of Singapore
+65 65165626
cqtbjd@nus.edu.sg
Dr Jean-Daniel Bancal
Centre for Quantum Technologies, National University of Singapore
+65 65165626
cqtbjd@nus.edu.sg
Professor Nicolas Gisin
University of Geneva, Switzerland
+41 2 2379 0502 (office) / +41 79 7762317 (mobile)
Nicolas.Gisin@unige.ch
University of Geneva, Switzerland
+41 2 2379 0502 (office) / +41 79 7762317 (mobile)
Nicolas.Gisin@unige.ch
Professor Antonio Acin
ICFO-The Institute of Photonic Sciences, Spain
+34 93 553 40 62
Antonio.Acin@icfo.es
ICFO-The Institute of Photonic Sciences, Spain
+34 93 553 40 62
Antonio.Acin@icfo.es
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