UA College of Science | July 16, 2012

With this month's global announcement that the Higgs boson, a subatomic particle, might have been found, the UA physicists involved in the hunt have much to celebrate.

A person stands in front of the huge ATLAS detector, one of six detectors that are part of the Large Hadron Collider near Geneva. The photo was taken before the detector was closed up. (Photo credit: Maximilien Brice, CERN)This artist's graphic shows the underground ATLAS detector positioned along the Large Hadron Collider's 17-mile subsurface tunnel at the Swiss-Franco border. Protons shoot along the tunnel and smash into each other with unprecedented impact speeds. (Photo courtesy of CERN)This visual representation shows a proton-proton collision that may have created a Higgs boson within the ATLAS detector. The bulls-eye in the center is the tube the proton beams shoot through. The red and blue lines shooting away from the proton beams represent 4 electrons created by the collision -- which is what physicists expect to see when a Higgs boson is created. (Photo courtesy of CERN)

Decades of work by University of Arizona physicists were rewarded by the recent announcement that the Higgs boson had likely been observed.

The Higgs boson, a key subatomic particle long predicted by theory, had not been detected until now.

“I’m excited – tremendously pleased,” said John Rutherfoord, a UA professor of physics who has been pursuing the Higgs boson for 28 years, most recently as part of an international group of physicists working on the Large Hadron Collider, or LHC. The UA is the only institution in Arizona involved with the LHC.

This is the first new fundamental particle discovered by physicists since 2000.

Physicists had hoped the LHC, the most powerful particle accelerator ever built, would be able to find the boson named for physicist Peter Higgs.

The LHC smashes protons together in a 17-mile circular tunnel about 100 yards under the Franco-Swiss border and is operated by the European Organization for Nuclear Research, known as CERN.

“We have found a new boson – and evidence that it’s the Higgs is very strong,” Rutherfoord said.

So far, all indications are promising. The new particle has a mass of about 125-126 giga-electron volts – within the range where the physicists expected to see the Higgs boson.

Even so, Rutherford said more analyses must be done before the new boson is definitively declared to be the Higgs: “We just don’t have enough data to say with the degree of certainty that scientists like to have.”

He and other UA physicists built part of a massive instrument called ATLAS that is inside the LHC. In addition to Rutherfoord, the UA-ATLAS research team includes UA physics professors Elliott Cheu, Kenneth Johns and Michael Shupe, and Erich Varnes, a UA associate professor of physics.

The team also includes research engineers and technicians, postdoctoral students, graduate students and undergraduates.

Physicists have developed “The Standard Model” to explain how the universe works. The Higgs boson is the only subatomic particle predicted by the model that physicists have not yet found.

Cheu said, “It’s a pretty good theory – with one problem. We’ve never seen the Higgs boson.”

Finding the Higgs would be a key validation of the Standard Model, he said.

The LHC has been regularly smashing protons together for two years, but the particle known as the Higgs boson is extremely hard to detect. Finding it requires analyzing the data generated by trillions of proton-proton collisions.

The UA's ATLAS team led the design, construction and installation of the Forward Calorimeter, an instrument within ATLAS that measures the position and the tremendous energies of the particles given off when the LHC’s proton beams collide.

The ATLAS detector and another detector called CMS have been accumulating more and more data the longer the LHC runs. And the researchers have become better and better at sifting through the mountains of data being generated.

“You don’t all of a sudden find it,” Rutherfoord said of the Higgs boson. “You accumulate data and you accumulate data and then finally you can say that you found it.”

Finding the Higgs is just one of the things the UA physicists expect to learn from the Large Hadron Collider. The collider may be able to help scientists learn more about dark matter or reveal other surprises that point the way to a better understanding of physics.

Rutherfoord said, “Dark matter is an extremely exciting possibility that we are hoping to discover."

At 150-feet long, 82 feet in diameter and weighing more than 7,700 tons, ATLAS, shorthand for A Toroidal LHC Apparatus, is the world's largest-volume particle physics detector ever built.

Approximately 700 physicists, engineers and graduate students from 44 U.S. institutions participate in the ATLAS collaboration. The U.S. Department of Energy and the National Science Foundation fund the U.S. participation in the Large Hadron Collider.

The whole ATLAS collaboration includes 3,000 physicists from 38 countries and 176 institutions.

Story Contacts:

Researcher Contact Information

John Rutherfoord

UA department of physics

520-621-2657

rutherfo@physics.arizona.edu

 

Michael Shupe

UA department of physics

520-621-2679

shupe@physics.arizona.edu

 

Elliott Cheu

UA department of physics

520-621-4090

elliott@physics.arizona.edu

 

Erich Varnes

UA department of physics

520-626-0217

varnes@physics.arizona.edu

 

Kenneth Johns

UA department of physics

520-621-6791

johns@physics.arizona.edu

 

Media Contact

Mari N. Jensen

UA College of Science

520-626-9635

mnjensen@email.arizona.edu