Matter and antimatter were created in equal amounts in the Big Bang but somehow the antimatter disappeared, resulting in the Universe, and everything in it, being made of the remaining matter.
Scientists from the Universities of Liverpool and Glasgow will use the final modules of the VErtex LOcator (VELO), a precision silicon detector, which has been delivered to CERN, the European Particle Physics Laboratory in Geneva.
Once assembled, VELO will be installed into the LHCb detector, one of four experiments that make up the Large Hadron Collider (LHC) particle accelerator, which is due to be switched on in November this year.
LHCb is designed to investigate the subtle differences between matter and antimatter in particles containing b (beauty) quarks.
VELO is an essential part of the experiment which will provide the unprecedented precision necessary to isolate them.
The LHC, located in a 27km underground tunnel which straddles France and Switzerland, will help answer some of the fundamental questions about the origins of our Universe and is set to change the future path of particle physics research.
Within the LHC, two beams of protons will be accelerated to close to the speed of light and then collided in one of the four experiments, which will each measure the outfall of particles.
Identifying b quarks
Professor Themis Bowcock, lead scientist from the University of Liverpool LHCb team, said: "The VELO gives us the precision we need not only to identify b quarks in a proton-proton collision, but to do so in real time.
"This allows us to isolate samples of b quarks for analysis in a way that would be impossible otherwise. It is the key to LHCb’s physics aims."
The VELO is unique in its design with the whole device (about a metre long) consisting of 42 silicon ‘modules’, spread along both sides of the proton beam (21 each side).
It actually sits inside a vacuum vessel – with a thin sheet of aluminium, know as RF foil, separating it from the primary vacuum inhabited by the proton beams.
The two halves of modules are mechanically moved in to within seven millimetres of the beam during data-taking, and out to a safe distance afterwards.
Dr Tara Shears, LHCb scientist from the University of Liverpool, explained: "To achieve optimal precision the silicon detectors need to be as close as possible to the beam.
"When operational 40 million proton proton interactions will occur per second inside LHCb and it is no mean feat that measurements of these collisions will take place in real time."
Scientists from the University of Glasgow are responsible for the reception and testing of the modules at CERN.
Dr Chris Parkes from University of Glasgow said: "Now that all 42 modules are on site we are busy testing before final installation in the detector, 100 metres underground."
You’ve read it. Now review it.
Date Published: April 12, 2007
More by this source
|
Print
|
Send to a friend
|
Rate & Comment
|
Keep up to date
If you found this item fun or informative, please let others know. Simply send to a friend or recommend it to even more people - on any of the following sites:
Latest Science News | reddit | digg.com | del.icio.us | rollyo | stumbleupon
More on antimatter...
UK physicist plans to delve into the secrets of antimatter
A physicist is leading a project which could change our understanding of the Big Bang.
Large Hadron Collider: Scientists' wish list for the LHC
When the Large Hadron Collider is up to full power, it will be crashing protons together 600 million times per second. After each impact, giant detectors will scour the subatomic wreckage looking for evidence of new physics.
Nobel prize for physics goes to work on fundamental laws of nature
Three researchers have won the Nobel prize for physics for their discovery of the hidden order that underlies the laws of nature.
