Large Electron-Positron Collider

From Wikipedia, the free encyclopedia

The LEP tunnel at CERN, now being filled with magnets for the LHC
The LEP tunnel at CERN, now being filled with magnets for the LHC

The Large Electron-Positron Collider (LEP) was one of the largest particle accelerators ever made. It was built at CERN, a multi-national center for research in nuclear and particle physics. LEP was a giant evacuated ring with a circumference of 27 kilometers built in a tunnel under the border of Switzerland and France. It was used from 1989 until 2000. To date, LEP is the most powerful accelerator of leptons ever built.

Contents

[edit] History

When the LEP collider started operation in 1989 it accelerated the electrons and positrons to a total energy of 45 GeV each to enable production of the Z Boson, which has a mass of approximately 91 GeV. The accelerator was upgraded later to enable production of a pair of W Bosons, each weighing approximately 80 GeV. LEP collider energy eventually topped at 104 GeV at the end in 2000. At the end of 2000, LEP was shut down and then dismantled in order to make room in the tunnel for the construction of the Large Hadron Collider (LHC).

[edit] Operation

An old RF cavity from LEP, now on display at the Microcosm exhibit at CERN
An old RF cavity from LEP, now on display at the Microcosm exhibit at CERN

The Super Proton Synchrotron (an older ring collider) was used to accelerate electrons and positrons to nearly the speed of light. These are then injected into the ring. As in all ring colliders, the LEP's ring consists of many magnets which force the charged particles into a circular trajectory (so that they stay inside the ring), RF accelerators which accelerate the particles with radio frequency (RF) waves and quadrupoles that focus the particle beam (i.e. keep the particles together). In this sense of the word, acceleration does not truly mean that the particles' velocities increase, as they already are very close to the speed of light, but that they gain kinetic energy and so become more massive, as mass and energy are equivalent by the theory of special relativity. When the particles are accelerated to maximum energy (and focused to so-called bunches), an electron and a positron bunch is made to collide with each other at one of the collision points of the detector. When an electron and a positron collide, they annihilate to a virtual particle, either a photon or a Z boson. The virtual particle almost immediately decays into other elementary particles, which are then detected by huge particle detectors.

[edit] Detectors

The Large Electron-Positron Collider had four detectors, built around the four collision points within underground halls. Each was the size of a small house and was capable of registering the particles by their energy, momentum and charge, thus allowing physicists to infer the particle reaction that had happened and the elementary particles involved. By performing statistical analysis of this data, knowledge about elementary particle physics is gained. The four detectors of LEP were called Aleph, Delphi, Opal, and L3. They were built differently to allow for complementary experiments.

[edit] Results

The results of the LEP experiments allowed precise values of many quantities of the Standard Model -- most importantly the mass of the Z boson and the W boson (which were discovered in 1983 at an earlier CERN collider) to be obtained -- and so confirm the Model and put it on a solid basis of empirical data.

Dr. Bagger on precision and the mass of the Z boson at CERN: "The experimenters found that the Z boson got heavier at certain times of the day. This was a very high-precision experiment. They discovered that the patterns of the particle getting heavier corresponded to the tides. The gravitational adjustments due to tides slightly changed the shape of the collider over the course of the day. After adjusting for tidal effects, they found that the Z boson was heavier in spring and lighter in fall. This was because there's a lake in Geneva near the detector, that is drained in Fall to make room for the spring snow-melt. So the bigger lake in the Spring was making the particle heavier. After correcting for both of these factors, they found that the particle got suddenly heavier multiple times during the day, at the same times. This was because a train runs near the detector whose electromagnetic fields were disturbing the experiment. This is how precise the experiment was."

Precision measurements of the shape of the Z boson mass peak constrained the number of light neutrinos in the standard model to exactly three. Near the end of the scheduled run time, data suggested very tentative but inconclusive hints that the Higgs particle might have been observed, a sort of Holy Grail of current high-energy physics. The run-time was extended for a few months, to no avail.

[edit] External links