by Wormholes, often considered staples of science fiction, are hypothetical cosmic structures that act as shortcuts, or tunnels, through the fabric of spacetime. Rooted in general relativity, these enigmatic bridges could potentially connect two disparate points in space and time, allowing them to travel faster than light and span the vast distances of the universe. While the existence of wormholes is still purely theoretical, their studies continue to intrigue scientists and spark curiosity about the unexplored reaches of the cosmos.
An innovative method overcomes a significant hurdle in scaling quantum prototypes.
A practical application for the much-anticipated but underused[{” attribute=””>quantum computing technology is within reach due to an innovative method that overcomes the significant challenge of scaling up these prototypes.
The invention, by a University of Bristol physicist, who gave it the name ‘counterportation’, provides the first-ever practical blueprint for creating in the lab a wormhole that verifiably bridges space, as a probe into the inner workings of the universe.
By deploying a novel computing scheme, revealed in the journal Quantum Science and Technology, which harnesses the basic laws of physics, a small object can be reconstituted across space without any particles crossing. Among other things, it provides a ‘smoking gun’ for the existence of a physical reality underpinning our most accurate description of the world.
Study author Hatim Salih, Honorary Research Fellow at the university’s Quantum Engineering Technology (QET) Labs, and co-founder of the start-up DotQuantum, said: “This is a milestone we have been working towards for a bunch of years. It provides a theoretical as well as practical framework for exploring afresh enduring puzzles about the universe, such as the true nature of spacetime.”
Image illustrating traversable local wormhole. Space is represented horizontally. Time runs vertically, upwards. The two quantum objects, one on either side, start off at the bottom. The complex quantum object to be counterported is the one on the right. As time elapses, the local wormhole gradually folds, then unfolds, space—allowing the object on the right to be reconstituted across. The saturation of the color red between the two objects represents the extent to which space is folded. The orange and the green vertical lines, corresponding to two local journeys in observable spacetime, indicate that no detectable information carriers were exchanged. Credit: Hatim Salih
The need for detectable information carriers traveling through when we communicate has been a deeply ingrained assumption among scientists, for instance, a stream of photons crossing an optical fiber, or through the air, allowing people to read this text. Or, indeed, the myriad neural signals bouncing around the brain when doing so.
This holds true even for quantum teleportation, which, Star Trek aside, transfers complete information about a small object, allowing it to be reconstituted elsewhere, so it is indistinguishable in any meaningful way from the original, which disintegrates. The latter ensures a fundamental limit preventing perfect copying. Notably, the recent simulation of a wormhole on Google’s Sycamore processor is essentially a teleportation experiment.
Hatim said: “Here’s the sharp distinction. While counterportation achieves the end goal of teleportation, namely disembodied transport, it remarkably does so without any detectable information carriers traveling across.”
Wormholes were popularised by the mega-hit movie Interstellar, which included physicist and Nobel laureate Kip Thorne among its crew. But they first came to light about a century ago as quirky solutions to Einstein’s gravity equation, as shortcuts in the fabric of spacetime. The defining task of a traversable wormhole, however, can be neatly abstracted as making space traversable disjunctly; in other words, in the absence of any journey across observable space outside the wormhole.
The pioneering research, fittingly completed to Interstellar’s spine-tingling background music, sets out a way to carry this task out.
“If counterportation is to be realized, an entirely new type of quantum computer has to be built: an exchange-free one, where communicating parties exchange no particles,” Hatim said.
“By contrast to large-scale quantum computers that promise remarkable speed-ups, which no one yet knows how to build, the promise of exchange-free quantum computers of even the smallest scale is to make seemingly impossible tasks – such as counterportation – possible, by incorporating space in a fundamental way alongside time.”
Plans are now in progress, in collaboration with leading UK quantum experts in Bristol, Oxford, and York, to physically build this otherworldly-sounding wormhole in the lab.
“The goal in the near future is to physically build such a wormhole in the lab, which can then be used as a testbed for rival physical theories, even ones of quantum gravity,” Hatim added.
“This work will be in the spirit of the multi-billion ventures that exist to witness new physical phenomena, like the Laser Interferometer Gravitational-Wave Observatory (
Reference: “From counterportation to local wormholes” by Hatim Salih, 2 March 2023, Quantum Science and Technology.
DOI: 10.1088/2058-9565/ac8ecd
The research was funded by the Engineering and Physical Science Research Council (EPSRC).
