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Europe’s Large Hadron Collider tests the bounds of physics – and budgets

Scientists look for technologies to push particles faster, better, and cheaper.

Collider part: The Compact Muon Solenoid, which weighs over 12,500 tons, is one of two detectors scientists will use to measure results from the collision of protons inside the Large Hadron Collider near Geneva. The collisions are expected to begin in September.


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If all goes well, this weekend a handful of protons will make their first, tentative entrance into the main rings of the world’s most powerful time machine.

It’s an important step toward the full-scale start-up of the Large Hadron Collider (LHC), a mammoth particle accelerator spanning the French-Swiss border. That start is expected in early September.

Physicists will accelerate beams of protons in opposite directions – each along its own nearly 17-mile circular path – to nearly the speed of light. Then, they will steer the hair-thin beams of protons into head-on collisions.

From the subatomic mayhem that ensues, physicists say they anticipate discoveries that will fill out the picture they have drawn during the past century of matter and the basic forces of nature – the so-called standard model. They also expect to see evidence of new physics beyond the standard model, including insights into the nature of dark matter and dark energy, which make up the vast majority of the energy and matter in the universe.

Yet even as scientists and engineers put the LHC through its final tests, researchers worldwide are exploring ways to build more-powerful, less-expensive accelerators. Results from the LHC will play a key role in determining how much more powerful they need to be. But one thing is clear, several physicists say: Attempts to use today’s technologies for tomorrow’s collider frontiers are likely to face virtually insurmountable cost and technical barriers.

“As you go up to higher energies, these facilities become more and more expensive,” says Dennis Kovar, associate director for high-energy physics in the US Department of Energy’s Office of Science. “If there are going to be next-generation colliders, one is going to have to have some breakthroughs in technology ... to be able to do it at an affordable price.”


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