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LHC Records 1M Collisions

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Three Iowa State University physicists who took winter trips to the Large Hadron Collider for meetings and experimental work are starting to see real data from the planet’s biggest science experiment – finally.

The multibillion-dollar collider made international news on Sept. 10, 2008, when it sent its first beam of protons around 17 miles of underground tunnel near Geneva, Switzerland (See: Collider Beams Up at CERN). But breakdowns in the machine’s high-current electrical connections forced a complete shutdown for more than a year of repairs and tests (See: LHC Repairs to Take Months).

Physicists worldwide cheered on Nov. 20, 2009, when the collider once again sent protons racing through its tunnel. Three days later, the machine recorded its first proton-proton collisions. And on Nov. 30, it set a world record when it accelerated two beams of protons to a total energy of 2.36 trillion electron volts.
Hadron.AtlasExp.jpg

Last month, the Atlas experiment at the Large Hadron Collider began recording proton-proton collisions at a record energy of 2.36 trillion eV. Image courtesy of the ATLAS experiment/Iowa State University.

Physicists at CERN, the European Organization for Nuclear Research, shut down the collider on Dec. 16 to prepare for even higher energy collisions later this year.

“The data look just beautiful,” said Soeren Prell, an Iowa State associate professor of physics and astronomy.

Prell has been looking at the first data recorded with the Atlas experiment’s silicon pixel detector. The pixel detector is the innermost part of Atlas, one of two giant, general-purpose detectors at the collider. Atlas will measure the paths, energies and identities of the particles created when protons or lead ions collide at unprecedented energies. The pixel detector uses 80 million pixels to make precise measurements as close to the particle collisions as possible.

Prell said the pixel detector already is sending physicists fairly clean data with very little background noise. But, he said, physicists still have to work to make sure the pixel detector is properly aligned and calibrated. It has a resolution down to 10-millionths of a meter and must be just as precisely aligned.

The detector’s data also has to be distributed to physicists around the world for study and analysis. Jim Cochran, an associate professor of physics and astronomy, is the Atlas experiment’s analysis support manager for the US. It is his job to make sure researchers have the data they need for their analyses.

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And, so far, the experiment’s analysis system has kept up with the data. But that is going to be a bigger challenge when the collider is turned back on in February and begins running at higher energies and much higher collision rates.

“One of the concerns I’ve had is whether we’ll be able to handle the data loads we’re expecting,” Cochran said. “We have to have our computing systems optimized so we can do it. We’ve already had 700,000 collision events, and that’s nothing compared to what’s coming.”

That’s just one of the reasons Chunhui Chen, an assistant professor of physics and astronomy, is telling people that big, new, Nobel-winning physics from the Large Hadron Collider won’t happen right away. According to Chen, there is just too much data to collect, distribute and analyze.

“This is a very big moment,” said Chen, who is working on the Atlas experiment’s pixel detector and the Atlas trigger system that recognizes and records interesting collision events. “Potentially, we’ll be able to see some new physics.”

That could include the Higgs boson, a particle predicted by the Standard Model of particle physics. The model theorizes that space is filled with a Higgs field and that particles acquire their masses by interacting with the field. Detection and study of the Higgs could answer basic questions about why matter has mass and how particles acquire mass.

Physicists also hope that the higher energies made possible by the Large Hadron Collider could answer big physics questions about matter and antimatter, dark matter, supersymmetry, extra dimensions, a grand unified theory or perhaps something entirely unexpected.

“One hundred years ago physicists discovered special relativity and quantum mechanics,” Chen said. “We know our understanding of physics is incomplete. We don’t know what’s beyond our understanding. And so this is going to be a long research program. It will take years of dedicated study to really unearth the secrets of the universe.”

For more information, visit: www.iastate.edu  

Published: January 2010
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astronomy
The scientific observation of celestial radiation that has reached the vicinity of Earth, and the interpretation of these observations to determine the characteristics of the extraterrestrial bodies and phenomena that have emitted the radiation.
higgs boson
The Higgs boson is a fundamental particle associated with the Higgs field, a field that permeates the universe and is responsible for giving mass to other fundamental particles through the mechanism known as the Higgs mechanism. The discovery of the Higgs boson was a significant milestone in particle physics as it confirmed a key part of the Standard Model of particle physics. Higgs field: An omnipresent field that interacts with particles, giving them mass. Particles that interact...
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
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