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by Clara Moskowitz
June 12, 2026
from
ScientificAmerican Website
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Clara Moskowitz
is chief of
reporters at Scientific American, where she covers
astronomy, space, physics and mathematics.
She has been at
Scientific American for more than a decade; previously
she worked at Space.com.
Moskowitz has
reported live from rocket launches, space shuttle
liftoffs and landings, suborbital spaceflight training,
mountaintop observatories, and more.
She has a
bachelor's degree in astronomy and physics from Wesleyan
University and a graduate degree in science
communication from the University of California, Santa
Cruz. |
Yuichiro Chino/Getty Images
Extremely curved spacetime
can warp
cause and effect,
creating
channels for
backward
communication...
If something is allowed by the laws of physics, then scientists can
assume that it probably exists.
Under that reasoning, certain exotic structures
of spacetime called
closed timelike curves may be
real - and they may allow a message to
travel from the future to the past.
A new study has calculated how much information can be
sent backward through time via
closed timelike curves.
Albert Einstein's general theory of
relativity predicts that these spacetime pathways can form under
intensely bending, rotating space - such as around a spinning black
hole.
"Spacetime can curve around so much that you
can be innocently going forward in time and then you meet
yourself in the past," says study co-author Seth Lloyd, a
quantum information scientist at the Massachusetts Institute of
Technology.
According to general relativity, in a rotating
black hole, the singularity - the theoretical point of infinite
density at the center - is really a one-dimensional ring, with
closed timelike curves arcing around it.
No one knows if these spacetime structures
actually exist in our universe, but they are plausible. We do know,
however, that black holes are plentiful in space and that most of
them spin.
"So they might very well exist," Lloyd says.
Inspiration for the study came in part from a
movie.
"In early 2025 I watched
the film Interstellar," says
Kaiyuan Ji, a graduate student at Cornell University who,
with his advisor Mark Wilde, collaborated with Lloyd on
the new research.
The findings were published recently in
Physical Review Letters (Retrocausal
Capacity of a Quantum Channel: Communicating through Noisy Closed
Timelike Curves).
In the movie, an astronaut played by Matthew McConaughey travels up
close to a black hole and sends a message to his daughter in the
past.
Ji realized the plot was mathematically
equivalent to a question he and his colleagues had posed in previous
research.
The group decided to investigate how best to use closed timelike
curves to transmit information between the future and the past.
"The strategy has a different structure than
communicating forward in time," Ji says.
"The key difference is that the sender in the
future has memory of what happened in the past, and that causes
a causal loop. You now have the ability to bend the probability
of success."
The researchers assumed that the channel might
have some noise - interference preventing the maximum amount of
information from passing through.
But the sender's memory of the past can help
counter that noise, they found.
"Let's say you drop a message into a black
hole in the future and it emerges from the same black hole in
the past, but the message gets corrupted or parts of it get
lost," Lloyd says.
"The receiver in the past can say, 'Hey, if
you're going to send me a message last Tuesday, I know the
closed timelike curve was super noisy then. Can you send
multiple copies or try on Wednesday?'"
The findings could have interesting implications
for quantum computing, says Giulio Chiribella, a quantum
information scientist at the University of Hong Kong, who was not
involved in the study.
Chiribella has studied the probability of
simulating closed timelike curves in a laboratory on Earth.
"We don't know if [these curves] exist in our
universe, but we do know that if they exist, they have powerful
consequences," he says.
"For example, they induce radically new
scenarios where the order of events becomes indefinite, boosting
quantum computation and quantum communication beyond the limits
of conventional setups."
In the past scientists have found that closed
timelike curves can't be used for paradoxical time travel.
An experiment in a 2011 paper (Closed
Timelike Curves via Postselection - Theory and Experimental Test of
Consistency) co-authored by Lloyd simulated these
pathways in a laboratory and effectively sent a photon (a particle
of light) back in time by less than a second.
The researchers were curious whether the photon
might be able to destroy the past version of itself - akin to a
person traveling back in time to kill their grandfather, thus
preventing themselves from ever being born.
The so-called
grandfather paradox is a
prickly aspect of time travel, but in the case of closed timelike
curves, it seems that quantum physics permits only self-consistent
versions of time travel.
In other words,
you can visit the past, but you can't change
the future - no grandfather murder allowed...
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