Search This Blog

Tuesday, June 7, 2011

Does Our Universe Live Inside a Wormhole?

Does Our Universe Live Inside a Wormhole?



A long time ago, a giant star collapsed in a universe much more significant than our own. Its implosion crammed so much mass and energy together that it created a wormhole to another universe. And inside this wormhole, our own universe was born. It may seem fantastic, but a theoretical physicist claims that such a scenario could help answer some of the most perplexing questions in cosmology.
Several facets of our universe need to be clarified. One is gravity. Scientists can't construct a mathematical formula that unites gravity with nature's three other basic forces: the strong and weak nuclear forces and electromagnetism. Another problem is dark energy, the mysterious phenomenon expanding our universe at an accelerating rate, even though gravity should be contracting it or slowing the expansion.
These conundrums may be a result of stopping the search for the riddle of the cosmos at the big bang, says Nikodem Poplawski of Indiana University in Bloomington. The Big Bang theory holds that our universe began as a single point—or singularity—about 13.7 billion years ago and has expanded outward ever since. Perhaps, Poplawski argues, we must consider that something existed before the Big Bang that gave rise to it.
Enter the wormhole. According to Poplawski's calculations, the collapse of a giant star in another universe could have created a wormhole, a space-time conduit to another universe. Conditions could have developed similar to those we associate with the Big Bang between these two openings, and therefore, our universe could have formed within the wormhole.
Such a scenario could address the quandaries about gravity and the expanding universe. If another universe existed before our own, gravity could be traced back to a point where it did unite with nuclear forces and electromagnetism. And if our universe is now expanding toward the wormhole's other end, this movement—rather than the elusive dark energy—could account for our expanding universe.
The calculations need further refinement, admits Poplawski, who will publish his findings on Monday in Physics Letters B. For one thing, they need to describe how the wormhole formed in the first place. And don't get any ideas about travelling between the universes, Poplawski adds. The physics of wormholes is similar to the physics of black holes. If you could ever pass through the wormhole's event horizon to visit the universe on the other side, you could never return. "You will be stuck," he says.
Cosmologist Martin Bojowald of Pennsylvania State University, University Park, won't even go that far. He thinks the way the paper treats the gravitational collapse into a wormhole is a bit "contrived." It would be difficult to imagine the idea has applications "beyond pure theory," he says.
Nevertheless, theorist Eduardo Guendelman of Ben-Gurion University of the Negev in Beersheba, Israel, finds the paper's way of describing the junction of two universes "very instructive." The key question, Guendelman says, is whether the matter necessary to construct the wormhole exists.


No comments:

Post a Comment