User Documents and Examples I
... C++ compiler, CLHEP, GNU make, Geant4 toolkit choices for visualization software ...
... C++ compiler, CLHEP, GNU make, Geant4 toolkit choices for visualization software ...
Document
... The other way to produce a magnetic field is by means of elementary particles such as electrons, because these particles have an intrinsic magnetic field around them. The magnetic fields of the electrons in certain materials add together to give a net magnetic field around the material. Such additio ...
... The other way to produce a magnetic field is by means of elementary particles such as electrons, because these particles have an intrinsic magnetic field around them. The magnetic fields of the electrons in certain materials add together to give a net magnetic field around the material. Such additio ...
MAGNETISM
... By rubbing a material with unaligned domains with a magnet, the domains will align themselves, forming a magnet. One of the best ways is to heat the material (like the magma from the mid-atlantic ridge) and then pass it through a magnetic field. When the material cools, its domains will have settled ...
... By rubbing a material with unaligned domains with a magnet, the domains will align themselves, forming a magnet. One of the best ways is to heat the material (like the magma from the mid-atlantic ridge) and then pass it through a magnetic field. When the material cools, its domains will have settled ...
Document
... LEP beam energy measurement I Precise beam energy by “resonant depolarisation” measurements A single beam of polarised e- is stored in the LEP accelerator and the measured precession frequency of e- spins allows Ebeam to be measured to a precision of <1 MeV (at Ebeam ~45 GeV) However, thiscan ...
... LEP beam energy measurement I Precise beam energy by “resonant depolarisation” measurements A single beam of polarised e- is stored in the LEP accelerator and the measured precession frequency of e- spins allows Ebeam to be measured to a precision of <1 MeV (at Ebeam ~45 GeV) However, thiscan ...
Antiproton Decelerator
The Antiproton Decelerator (AD) is a storage ring at the CERN laboratory in Geneva. It was built as a successor to the Low Energy Antiproton Ring (LEAR) and started operation in the year 2000. The decelerated antiprotons are ejected to one of several connected experiments.