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Higgs Boson Particle May Spell Doom For the Universe

proton-proton collisions showing what may be the Higgs boson particle
The mass of the Higgs boson particle, possibly uncovered at the Large Hadron Collider (LHC) in Geneva, may mean doom for our universe. Here, proton-proton collisions at the LHC showing events consistent with the Higgs. (Image credit: CERN/CMS/Taylor, L; McCauley, T )

BOSTON — A subatomic particle discovered last year that may be the long-sought Higgs boson might doom our universe to an unfortunate end, researchers say.

The mass of the particle, which was uncovered at the world's largest particle accelerator — the Large Hadron Collider (LHC) in Geneva — is a key ingredient in a calculation that portends the future of space and time.

"This calculation tells you that many tens of billions of years from now there'll be a catastrophe," Joseph Lykken, a theoretical physicist at the Fermi National Accelerator Laboratory in Batavia, Ill., said Monday (Feb. 18) here at the annual meeting of the American Association for the Advancement of Science.

"It may be the universe we live in is inherently unstable, and at some point billions of years from now it's all going to get wiped out," added Lykken, a collaborator on one of the LHC's experiments. [Gallery: Search for the Higgs Boson]

The Higgs boson particle is a manifestation of an energy field pervading the universe called the Higgs field, which is thought to explain why particles have mass. After searching for decades for proof that this field and particle existed, physicists at the LHC announced in July 2012 that they'd discovered a new particle whose properties strongly suggest it is the Higgs boson.

To confirm the particle's identity for sure, more data are needed. But many scientists say they're betting it's the Higgs.

"This discovery to me was personally astounding," said I. Joseph Kroll, a University of Pennsylvania physicist who also works at the LHC. "To me, the Higgs was sort of, it might be there, it might not. The fact that it's there is really a tremendous accomplishment."

And finding the Higgs, if it's truly been found, not only confirms the theory about how particles get mass, but it allows scientists to make new calculations that weren't possible before the particle's properties were known.

For example, the mass of the new particle is about 126 billion electron volts, or about 126 times the mass of the proton. If that particle really is the Higgs, its mass turns out to be just about what's needed to make the universe fundamentally unstable, in a way that would cause it to end catastrophically in the far future.

That's because the Higgs field is thought to be everywhere, so it affects the vacuum of empty space-time in the universe.

"The mass of the Higgs is related to how stable the vacuum is," explained Christopher Hill, a theoretical physicist at the Fermi National Accelerator Laboratory. "It's right along the critical line. That could either be a cosmic coincidence, or it could be that there's some physics that's causing that. That's something new, which we didn't know before."

Strikingly, if the Higgs mass were just a few percent different, the universe wouldn't be doomed, the scientists said.

But even if the universe is in for an unfortunate end, there is at least one reason for consolation.

"You won't actually see it, because it will come at you at the speed of light," Lykken said. "So in that sense don't worry."

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Clara Moskowitz

Clara Moskowitz is a science and space writer who joined the team in 2008 and served as Assistant Managing Editor from 2011 to 2013. Clara has a bachelor's degree in astronomy and physics from Wesleyan University, and a graduate certificate in science writing from the University of California, Santa Cruz. She covers everything from astronomy to human spaceflight and once aced a NASTAR suborbital spaceflight training program for space missions. Clara is currently Associate Editor of Scientific American. To see her latest project is, follow Clara on Twitter.