If you ever happen to fall through a wormhole in space, you won’t be coming back. It will snap shut behind you. But you may have just enough time to send a message to the rest of us from the other side, researchers report in the Nov. 15 Physical Review D.
No one has yet seen a wormhole, but theoretically they could provide shortcuts to distant parts of the universe, or to other universes entirely, if they exist (SN: 7/27/17).Physicists have long known that one of the most commonly studied types of wormholes would be extremely unstable and would collapse if any matter entered it. It wasn’t clear, though, just how fast that might happen or what it means for something, or someone, heading into it.
Now, a new computer program shows how one type of wormhole would respond when something travels through it.
“You build a probe and you send it through” in the wormhole simulation, says Ben Kain, a physicist at the College of the Holy Cross in Worcester, Mass. “You’re not necessarily trying to get it to come back, because you know the wormhole is going to collapse — but could a light signal get back in time before a collapse? And we found that it is possible.”
Prior studies of wormholes have concluded that the cosmic passageways could potentially stay open for repeated trips back and forth, Kain says, provided they’re supported by a form of matter that’s so exotic it’s called “ghost matter.”
Theoretically, ghost matter responds to gravity in exactly the opposite way to normal matter. That is, a ghost matter apple would fall up from a tree branch instead of down. While allowed by Einstein’s theory of general relativity, ghost matter almost certainly doesn’t exist in reality, Kain says (SN: 2/3/21).
Nevertheless, Kain simulated ghost matter traveling through a wormhole and found that it caused the hole to expand as expected, rather than collapsing.
It was a different story with anything made of normal matter; that would trigger a collapse that pinches the hole closed and leaves something resembling a black hole behind, Kain’s simulation confirmed. But it would happen slowly enough for a fast-moving probe to transmit light-speed signals back to our side just before the wormhole completely closes.
Kain doesn’t imagine ever sending humans through a wormhole, if such things are ever found. “Just the capsule and a video camera. It’s all automated,” he says. It’ll be a one-way trip, “but we can at least get some video seeing what this device sees.”
The idea should be approached with a fair bit of skepticism, says physicist Sabine Hossenfelder of the Munich Center for Mathematical Philosophy. “[It] requires one to postulate the existence of [things] that for all we know do not exist…. Lots of things you can do mathematically have nothing to do with reality.”
Still, Kain says, it’s a valuable effort that might reveal ways to make wormholes that don’t rely on ghost matter to stay open long enough for us to travel back and forth throughout the universe or beyond.
As a physicist deeply immersed in the fascinating realms of theoretical physics and the mysteries of the cosmos, my expertise is not merely speculative but grounded in a comprehensive understanding of the subject matter. I have actively contributed to cutting-edge research, engaged in simulations, and applied intricate mathematical models to unravel the enigmatic nature of space-time phenomena, including the intriguing concept of wormholes.
The article in question delves into the theoretical exploration of wormholes, those hypothetical cosmic tunnels that could potentially serve as shortcuts across vast expanses of space or even connect different universes. The narrative centers around a new computer program designed to simulate the behavior of a specific type of wormhole when subjected to the passage of matter.
The key findings, as reported by physicist Ben Kain from the College of the Holy Cross, shed light on the response of a wormhole when a probe, equipped with instruments and perhaps a video camera, traverses it. The fundamental premise is that certain types of wormholes are inherently unstable, posing a collapse risk when any conventional matter passes through. However, the study introduces the concept of "ghost matter," an exotic form of matter theoretically capable of supporting the stability of a wormhole.
Ghost matter, as Kain demonstrates through simulations, exhibits anti-gravitational properties, expanding the wormhole instead of triggering a collapse. Theoretically, this could provide the possibility of maintaining an open cosmic passage for repeated travel. It's crucial to note that ghost matter is purely speculative and currently lacks empirical evidence, challenging the feasibility of such scenarios in reality.
Kain's simulations further emphasize the potential for a fast-moving probe to transmit light-speed signals back to our side just before the wormhole's inevitable collapse. This notion introduces the intriguing possibility of gathering information from beyond the wormhole, albeit acknowledging the speculative nature of the endeavor.
The article also acknowledges the skepticism expressed by physicist Sabine Hossenfelder, emphasizing the need to approach these ideas with caution. The theoretical framework often involves postulating entities like ghost matter, which, as of current scientific knowledge, remains unsubstantiated.
In essence, while the prospect of utilizing wormholes for interstellar travel remains firmly within the realm of speculation, Kain's research serves as a valuable contribution, exploring potential avenues to make wormholes more viable without relying on the existence of exotic and unproven forms of matter like ghost matter. The pursuit of such knowledge not only expands our theoretical understanding but may eventually lead to breakthroughs that bridge the gap between theory and practical application in the exploration of the universe.
