New observations capture evidence of unimaginably fast expansion of universe in its infancy.
In an achievement hailed as astounding, scientists have detected ripples made in the fabric of the universe just after the Big Bang, providing definitive evidence that that the universe underwent a fast and incomprehensibly massive growth spurt in its earliest infancy.
If the new findings are confirmed, they could very well earn the Nobel Prize for the scientists behind the research, says astrophysicist Xavier Siemens of the University of Wisconsin, Milwaukee.
"This is an amazing discovery," he said. To find such strong evidence of these waves "is really just astounding."
If the data are correct, "it's a really profound discovery for cosmology," says Cornell University cosmologist Rachel Bean. "It's a phenomenal announcement."
In the thinnest sliver of a second just after the Big Bang, the universe was smaller than the end of your pinky finger. To explain its current state, scientists have posited an event called "inflation," when space expanded violently and almost instantaneously, growing roughly by 100 trillion trillion times, said cosmologist Daniel Baumann of the University of Cambridge.. . That should have magnified tiny ripples in the universe called primordial gravitational waves, which in turn left a stamp on light created some 13.5 billion years ago.
That light still pervades the cosmos today as a faint glow invisible to the naked eye called the cosmic microwave background. A team of U.S. scientists announced Monday that they'd used a telescope in Antarctica to detect a telltale "curl" in the microwaves' orientation – a pattern that's the fingerprint of gravitational waves. Overturning expectations, the researchers said the evidence for the patterned microwaves was much less subtle than had been predicted.
"This has been like looking for a needle in a haystack," the University of Minnesota's Clem Pryke, a co-leader of the BICEP team, said in a statement, "but instead we found a crowbar."
Einstein predicted the existence of such ripples a century ago, but thought they might be too faint to be detected.
The findings are being hailed as the "smoking gun" of the inflation theory, which some scientists have scorned as inadequate. These results should help remove the last traces of doubt that inflation is the best way to explain the current status of the universe, scientists said.
Until now, "there was always this nagging doubt in me" about inflation, Baumann said. But "once (the new finding) is confirmed, I do believe it's the smoking gun."
The results, from what's known as the BICEP2 experiment, also provide the first data on what space was like at an extremely early age. Until now there'd been lots of theories on the traits of the infant universe, but no direct evidence. Scientists had long hoped that primordial gravitational waves would allow such insights.
"That's always been the promise," says experimental physicist Gregory Harry of American University, also a member of the LIGO collaboration, a group of scientists searching for gravitational waves. "Here BICEP has done it. They've got data from the very earliest moment in the universe."
The announcement is "extraordinarily exciting for the cosmology community," said Bean. "It sends out waves, and not just gravitational waves."