The new step in the startup phase indicated continued smooth operation of the Large Hadron Collider since its repairs following a spectacular collapse last year.
updated 11/24/2009 8:05:27 PM ET 2009-11-25T01:05:27

The world's largest atom smasher has used its accelerator to speed up proton beams for the first time as scientists moved ahead in efforts to learn more about the universe.

The $10 billion Large Hadron Collider showed Tuesday it could raise the energy of the proton beams whizzing around the massive machine by an initial 20 percent.

"It was just a preliminary test," said James Gillies, spokesman for the European Organization for Nuclear Research, also known as CERN. "It's all going very well."

Tuesday's step indicated further good news for the collider since months of repairs following its spectacular collapse last year. The latest phase began Friday night when the first proton beams circulated each way around the 17-mile (27-kilometer) tunnel under the Swiss-French border.

The operators then got the beams to run simultaneously in opposite directions through fire-hose-sized pipes 11,000 times a second around the ring, zooming by at nearly the speed of light through temperatures colder than outer space.

Ultimately, the collider aims to create conditions like they were 1 trillionth to 2 trillionths of a second after the Big Bang — which scientists think marked the creation of the universe billions of years ago. Physicists also hope the collider will help them see and understand other suspected phenomena, such as dark matter, antimatter and supersymmetry.

On Monday, the collider's four massive detectors saw the first collisions between protons as the beams crossed each other at set points in rooms the size of cathedrals 100 meters (300 feet) underground.

Physicists say the beam is of superb quality, with the protons tightly packed into hairlike lines and guided by 1,600 superconducting magnets — some of them 15 meters (50 feet) long — around the ring.

While the initial collisions were a side effect, intentional hits could begin within the next 10 days, mainly to check how the machine is working, Gillies said. The initial collisions are needed to calibrate the machine.

Gillies said Tuesday the energy of the proton beam was increased to 540 from 450 billion electron volts, still a long way from the power that will be needed for new discoveries in the makeup of the universe and matter. Those discoveries might start happening in the first half of next year.

Interactive: Inside the big bang machine (on this page) "They set in process the procedure to ramp the machine up to the 1.2 TeV (trillion electron volts) that we want to get to this year," Gillies said.

That level would make the Geneva machine the world's most powerful collider, overtaking the Tevatron at Fermilab near Chicago, which operates at 1 trillion electron volts.

The Geneva accelerator automatically stopped when it rose to about 540 billion electron volts, about 90 billion electron volts higher than it had been operating so far, Gillies said.

After that, the proton beam was halted Tuesday for maintenance checks on the machine, he said.

The collider's first science test will take place in January or early February, when scientists plan to start deliberately crashing protons into each other to see what they can discover about the makeup of the universe and its tiniest particles.

Physicists said the discoveries could begin after the collider reaches 3.5 TeV in each direction.

The collider was started with great fanfare Sept. 10, 2008, only to be heavily damaged by an electrical fault nine days later. It took 14 months to repair and add protection systems to the machine before it was restarted. The overall price of repairs and improvements is expected to cost $40 million, according to CERN.

The long-term goal, after more modifications, will be to run the proton beams at 7 TeV in each direction — with seven times the energy for collisions that is available at Fermilab.

The higher the energy and the greater the number of protons in the beam, the more likely it will be that the scientists will discover particles and forces.

"It depends on how kind nature is to us," said CERN Director-General Rolf Heuer.

Still, it could take several years before the collider discovers the elusive Higgs boson, a particle that theoretically gives mass to other subatomic particles — and thus everything in the universe, said physicist Tejinder S. Virdee.

That is because the Higgs boson is believed to be hard to see and needs powerful energy to be revealed.

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Photos: How the biggest collider was built

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  1. Heart of the machine

    A worker stands inside the ATLAS detector, surrounded by its eight toroidal magnets, just before the installation of the machine's calorimeter. ATLAS, the largest particle detector at Europe's Large Hadron Collider, sits inside an underground cavern as big as a cathedral. (Maximilien Brice / CERN) Back to slideshow navigation
  2. Mission control

    Members of the ATLAS detector team monitor operations at their control room on the campus of Europe's CERN particle-physics research center. A cutaway view of the particle detector can be seen on the computer screen at far right. (Claudia Marcelloni / CERN) Back to slideshow navigation
  3. Down the hole

    The last of 1,746 superconducting magnets is lowered into the Large Hadron Collider's beamline tunnel via a specially constructed pit in April 2007, as seen in this fish-eye view. Dipole magnets like this one produce a magnetic field that is 100,000 times stronger than Earth's, to bend beams of subatomic particles around the circular accelerator. (Claudia Marcelloni / CERN) Back to slideshow navigation
  4. Making the connection

    A welder works on the interconnection between two of the Large Hadron Collider's superconducting magnet systems in the collider tunnel. (Maximilien Brice  / CERN) Back to slideshow navigation
  5. Wheel of fortune

    One of the wheel-shaped slices of the ATLAS muon detector is lowered into a cavern for assembly into a giant device designed to look for evidence of exotic subatomic particles such as the Higgs boson. The Higgs particle is thought to play a key role in producing the property of mass in the universe. (Claudia Marcelloni & J. Pequenao / CERN) Back to slideshow navigation
  6. The theorist and the experiment

    World-famous theoretical physicist Stephen Hawking takes a look at the Large Hadron Collider's underground beamline during a visit in September 2006. (CERN) Back to slideshow navigation
  7. Pulling the trigger

    Each experiment at the Large Hadron Collider requires a "trigger," a combination of hardware and software that decides which collisions are significant enough to pass along for further analysis. This is a fish-eye view inside the trigger chambers for the ALICE detector's muon spectrometer. (Aurelien Muller / CERN) Back to slideshow navigation
  8. Inside the big bang

    A technician from the ALICE installation team works on gas pipes for the detector. ALICE is designed to study lead-ion collisions so intense that they re-create the conditions that existed just after the big bang. (A. Saba & Mona Schweizer / CERN) Back to slideshow navigation
  9. Cycles within cycles

    Technicians often use bicycles to get around the Large Hadron Collider's 17-mile-round tunnel. (Maximilien Brice / CERN) Back to slideshow navigation
  10. Dwarfed by science

    The LHCb detector is designed to study why matter dominates over antimatter in the universe. The worker peeking out from the concrete barriers at left is dwarfed by the detector's lip-shaped magnet assembly at right. (CERN) Back to slideshow navigation
  11. The PC farm

    CERN's Computer Center stores the quadrillions of bytes of data generated by experiments at the Large Hadron Collider and distribute the information to thousands of researchers around the world, using a network known as the LHC Computing Grid. (Maximilien Brice / CERN) Back to slideshow navigation
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Interactive: Inside the big bang machine


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