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Physicists Gear Up for Huge Data Flow

University of Nebraska researchers build a computer center to handle the flood of data expected from the world's next-generation particle accelerator

Photograph of the compact muon solenoid detector at CERN.

The Compact Muon Solenoid detector at the European laboratory CERN.
Credit and Larger Version

August 7, 2008

University of Nebraska-Lincoln particle physicists Ken Bloom and Aaron Dominguez have teamed up with computer scientist David Swanson to build a computing center for the benefit of scientists at their university and across the country. The center's goal is to manage the flood of information that will pour from the world's next-generation particle accelerator, the Large Hadron Collider (LHC), an underground ring 27 kilometers around and located at the European Centre for Nuclear Research (CERN) in Geneva, Switzerland. 

Detectors stationed around the LHC ring will produce 15 trillion gigabytes of data every year, data that will be farmed out to computing centers worldwide. The Nebraska center will allow physicists from many universities to analyze data from the Compact Muon Solenoid (CMS) experiment--a more than 12,000-ton detector that will record tracks created by hundreds of particles emerging from each collision in the accelerator--while also providing computing power for researchers in other scientific fields.

As CMS began looking for computing centers to host its data, professors Bloom and Dominguez considered whether such a project would suit the University of Nebraska.

"After talking with David Swanson, who directs our Research Computing Facility, we realized that this was an ideal project for us to collaborate on," said Bloom.

In the LHC computing model, data from the experiments will flow through tiers. The Tier 0 center at CERN takes the data directly from the experiments, stores a copy and sends another to Tier 1 sites. CMS has seven Tier 1 sites in seven nations, and each site partitions its portion of the data, based on the types of particles detected, and sends these sub-samples off to Tier 2 sites. At the Tier 2 sites, researchers and students finally get their hands on the data. CMS has 30 such sites--seven in the U.S., one of which is at the University of Nebraska.

Physicists will use the data stored at these sites to search for never-before-seen particles or extra dimensions of space by submitting specialized programs to run on the data. With forty U.S. institutions involved in the CMS collaboration, the seven centers will see a lot of traffic.

One of the challenges of building a Tier 2 site is preparing it for heavy data flow. Already, the Nebraska group has achieved the fastest transfer rates in the national network that connects Fermi National Accelerator Laboratory, the U.S. Tier 1 site, with the U.S. Tier 2 sites.

"We are really good at moving data from Fermilab to our Tier 2 center," says Bloom without pretension, having achieved the fastest rates for any Tier 1-to-Tier 2 connection worldwide. "We can manage a terabyte an hour easily, and a terabyte in half an hour is possible."

Because the LHC will produce so much data, the terabyte, or 1,000 gigabytes, is the standard unit of data among scientists involved with LHC computing.

Apart from building lightning-fast network connections, Bloom and Dominguez are creating a computing center whose benefits extend beyond particle physics research. According to Dominguez, "It's a challenge to build a facility that could be effectively shared with a worldwide community and local researchers, to make something bigger, better, more useful to university research as a whole."

With this goal in mind, they designed a system that could support parallel computations. Programs that perform multiple, simultaneous calculations on different processors and bring the results together at the end are powerful tools for chemists and nanoscientists in particular. As the CMS Tier 2 site at the University of Nebraska is part of the U.S. Open Science Grid, researchers from many fields will analyze data using the university's computing power during times when CMS researchers aren't keeping the site busy.

-- Katherine McAlpine, U.S. Large Hadron Collider Communications katie.mcalpine@cern.ch

This Behind the Scenes article was provided to LiveScience in partnership with the National Science Foundation.

Ken Bloom
Aaron Dominguez
David Swanson

Related Institutions/Organizations
University of Nebraska-Lincoln


Related Programs
Elementary Particle Physics

Related Awards
#0545593 CAREER: Top-Quark Physics, Computing and Software at the Large Hadron Collider

Total Grants

Related Websites
Behind the Scenes: Physicists Gear Up For Huge Data Flow: http://www.livescience.com/4885-physicists-gear-huge-data-flow.html
Behind the Scenes:Building a Machine to Search for Cosmic Secrets: http://www.livescience.com/2382-building-machine-search-cosmic-secrets.html

Illustration of a simulation of a proton-proton collision at the Large Hadron Collider.
A simulation of a proton-proton collision at the Large Hadron Collider.
Credit and Larger Version

Ken Bloom (left), Aaron Dominguez (top), and  David Swanson (bottom) of the University of Nebraska.
Ken Bloom (left), Aaron Dominguez (top), and David Swanson (bottom) of the University of Nebraska.
Credit and Larger Version

Simulation of a possible signature that a Higgs boson particle may leave in the LHC detector.
Simulation of a possible signature that a Higgs boson particle may leave in the LHC detector.
Credit and Larger Version

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