Stanford University

News Service



CONTACT: Stanford University News Service (650) 723-2558

Asymmetric B Factory

STANFORD -- The Asymmetric B Factory is a high-energy physics facility being built at the Stanford Linear Accelerator Center (SLAC). The $177 million project is a collaborative effort among SLAC, the Lawrence Berkeley National Laboratory and the Lawrence Livermore National Laboratory.

Known as a particle collider, the B Factory will accelerate two beams of subatomic particles to nearly the speed of light and cause them to collide. Such collisions create other subatomic particles that help scientists better understand the fundamental principles underlying all matter.

Construction of the B Factory began in 1994. It is funded by the U.S. Department of Energy. Its completion is currently scheduled for 1998, after which there will be a commissioning process lasting until early 1999.

In parallel with the collider construction, an international collaboration of scientists and engineers is building a 1,000-ton particle detector for the facility. The detector is estimated to cost more than $80 million, almost one-third of which will come from foreign sources. More than 500 physicists from 78 institutions in 10 countries are participating in its design and construction.

The B Factory is a major upgrade and conversion of an older SLAC collider known as PEP. A second ring of magnets, an improved radio-frequency power system and a better vacuum system are being added in the existing tunnel, which is more than a mile in circumference. Electrons will circulate through the original ring, now being refurbished, while their antimatter counterparts ­ called "positrons" ­ will circulate the opposite direction in the new ring. Collisions between the two beams will occur at a crossover point, also known as the interaction point, which is surrounded by the detector.

What distinguishes the B Factory from previous colliders (and the reason it is called asymmetric) is that the electron beam energy will be different from that of the positron beam. Past colliders have generated electron and positron beams of equal energy. The B Factory, by contrast, will produce an electron beam with three times the energy of the positron beam. As a consequence, most of the new particles created will be thrown forward in the direction of the electron beam. This feature will allow scientists to pinpoint where the particles disintegrate and to measure their lifetimes and other properties more accurately than can be done at equal-energy colliders.

The B Factory is specifically engineered to produce millions of massive, short-lived subatomic particles called B mesons. During the past decade physicists around the world have recognized that B mesons provide the best opportunity to study a fundamental difference between matter and antimatter known as CP violation. This phenomenon, originally discovered in 1963, makes it slightly harder to transform matter into antimatter than vice versa. CP violation is thought to be a crucial part of the reason that there is essentially no antimatter remaining in the universe today.

Antimatter is identical to ordinary matter except that it has the opposite electrical charge. Electrons, for example, have a negative charge while their antiparticles, positrons, are positive; they both have exactly the same mass, however, and ­ apart from the difference in sign ­ behave the same way in electromagnetic fields. When a particle and its antiparticle meet, they completely annihilate each other in a flash of pure energy. This is what happens to the electrons and positrons that collide in the B Factory. Then, a fraction of an eye-blink later, the energy materializes as new subatomic particles.

For more than 30 years after its discovery in 1932, antimatter was thought to behave exactly like matter in every regard. But this similarity led to a major cosmological puzzle when the Big Bang became the accepted theory of the origin of the universe. If, as expected, equal amounts of matter and antimatter were created in the Big Bang, then why didn't they just annihilate each other to the point at which only energy remained? Why is there solid ground to stand on today?

The discovery of CP violation suggested a possible answer to this conundrum, by allowing a small excess of matter over antimatter to arise. That would mean that some matter had to remain after the annihilations ceased.

To determine whether this explanation is adequate, however, physicists need a much better and more complete understanding of CP violation. That understanding is what the B Factory is designed to provide.


A high-quality or color graphic is available from Michael Riordan, SLAC, (415) 926-2613.


Download this release and its related files.

The release is provided in Adobe Acrobat format. Any images shown in the release are provided at publishing quality. Additional images also may be provided. Complete credit and caption information is included.

© Stanford University. All Rights Reserved. Stanford, CA 94305. (650) 723-2300. Terms of Use | Copyright Complaints

© Stanford University. All Rights Reserved. Stanford, CA 94305. (650) 723-2300. Terms of Use | Copyright Complaints