-- SLAC's major high-energy physics program for the coming decade will enable scientists to investigate the matter-antimatter symmetry in nature. Masthead1
 
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News and press releases

The 2008 Nobel Prize in Physics was awarded today to Kobayashi, Maskawa, and Nambu for their work on symmetry breaking and CP violation. Understanding the origins of CP violation is one of the primary goals of the experimental programs of both the BABAR and Belle experiments, which were mentioned by name in the Nobel press release. The BABAR Collaboration has prepared a statement explaining the meaning and importance of this work. See also related articles at:  SLAC Today   Nature   Science   Symmetry Magazine
(October 7, 2008)

Spectacular physics from BABAR at ICHEP 2008
The BABAR  Collaboration  presented more than 90 new results in 22 talks at ICHEP08, the 34th International Conference on High Energy Physics in Philadelphia, Pennsylvania USA.
(August 1, 2008)

BABAR Observes the Ground State of Bottomonium 
On July 7, the BABAR Collaboration reported the first observation of the ground state of the b-anti-b quark system ("bottomonium") to Physical Review Letters. The ground state, called the ηb  ("eta-sub-b"), was seen in the decay Υ(3S) γηb. [read more...]. (July 8, 2008)

Updated: December 08, 2008

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BaBar Image Gallery
image gallery border Wide angle view of the BaBar Detector BaBar Image Gallery. Click on the orange dot for more information about each image.
Looking down on the BaBar Detector during construction
Close-up view of technicians working on the BaBar Detector
DIRC Chamber of the BABAR Detector
Silicon Strip Detector
3-D renderings of the BaBar Detector
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For each particle of matter there exists an equivalent particle with opposite quantum characteristics, called an anti-particle. Particle and anti-particle pairs can be created by large accumulations of energy and, conversely, when a particle meets an anti-particle they annihilate with intense blasts of energy. At the time of the big-bang, the large accumulation of energy must have created an equal amount of particles and anti-particles. But in  everyday life we do not encounter anti-particles. The question, therefore, is "What has happened to the anti-particles?"

BABAR is a High Energy Physics experiment located at SLAC National Accelerator Laboratory, near Stanford University, in California.

The goal of the experiment is to study the violation of charge and parity (CP) symmetry in the decays of B mesons. This violation manifests itself as different behaviour between particles and anti-particles and is the first step to explain the absence of anti-particles in everyday life.

To study CP violation the BABAR experiment exploits the 9.1 GeV electron beam and the 3 GeV positron beam of the PEP-II accelerator. The two beams collide in the center of the experiment, producing Υ(4S) mesons which decay into equal numbers of B and anti-B mesons.

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