A team of physicists claims to have moved light from one side of time to the other simultaneously; that is, a kind of quantum trick to move a photon (particle of light) forward and backward in time.
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The quantum experiment in which a particle of light
has traveled back and forth in time at the same time has been demonstrated by
two independent research groups. Can a photon exist in both states of time at
the same time?
How have they achieved it?
The scientists involved in both experiments have
achieved this thanks to a combination of two principles that are part of the
strange world of quantum mechanics and using a special optical crystal: the
convergence of quantum superposition and the symmetry of charge, parity and
time reversal. (CPT), which describe the physical properties of atoms and
subatomic particles.
Thanks to this effect, splitting a photon through a crystal produces a
counterintuitive behavior or rule. The clearest example of quantum superposition
we know from the hand of Schrödinger and the famous hypothetical cat that is
considered both alive and dead due to the fact that its life is in the hands of
a random subatomic event that takes place and has no place until observed. On
the other hand, the second law, symmetry of charge, parity, and time reversal,
states that any system containing particles will obey the same physical laws
even if the charges, spatial coordinates, and motions through time of the
particles are invest. This makes it possible for an overlapping particle to
travel both forward and backward in time .
By measuring the polarization of the
photons during the experiment, previously recombining the overlapping photons
moving through another crystal, they found a quantum interference pattern: a
pattern that could only and exclusively occur if the same photon moved in both
directions. That's right: a photon that seemed to travel simultaneously along
and backward on the arrow of time.
If confirmed, as the studies are pending peer review
and available on the arXiv preprint server, placing a particle of light in an
overlay to travel both forward and backward in time could prove useful for
computation. quantum (and not so much to allow us time travel, which is surely
what many readers are thinking). And it is that it would not have an immediate
practical use, but perhaps it would have implications for quantum computers,
even helping to develop a theory of quantum gravity. We will soon know if this
exotic physics experiment leads to new paths in quantum physics.
Time travel would be possible, but only
in parallel time lines
Reference: Experimental superposition of time directions
Teodor Strömberg, Peter Schiansky, Marco
Túlio Quintino, Michael Antesberger, Lee Rozema, Iris Agresti, Časlav Brukner,
Philip Walther Quantum Physics
https://doi.org/10.48550/arXiv.2211.01283
Experimental demonstration of
input-output indefiniteness in a single quantum device
Yu Guo, Zixuan Liu, Hao Tang, Xiao-Min
Hu, Bi-Heng Liu, Yun-Feng Huang, Chuan-Feng Li, Guang-Can Guo, Giulio
Chiribella Quantum Physics
https://doi.org/10.48550/arXiv.2210.17046
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