Finding The Higgs Boson

Continuing this theme of stuff that attracts skeptics, how about the Higgs boson? As of right now, it really is just hypothetical. There's no observational evidence for it – but check back in a year or so.

In the meantime, here's a good short summary of the observations that physicists need to make, and when something might turn up.

Finding The Higgs Boson

The Higgs’ ministrations are usually hidden away in the vacuum, but if enough energy is brought to bear in a tiny volume of space---at the point where two energetic particles collide---then the Higgs can be turned into an actual particle whose existence can be detected. Theoretical calculations made using the standard model of particle physics combined with previous experiments serve to limit the possible range of masses for the Higgs particle. Right now that mass is thought to be larger than 114 GeV but smaller than about 190 GeV.

And in spite of all the publicity that the Large Hadron Collider is getting, the discovery could actually be made as a result of experiments which are already ongoing at the Tevatron:

The Tevatron delivers more than enough energy to create a particle in that energy range. The main issue, then, is luminosity, or the density of beam particles crashed together per second. The Tevatron recently established a record high luminosity: 3.1 × 10³² per cm² per second. What would a Higgs event look like? One speaker at the meeting, Brian Winer (Ohio State), said that the “most Higgs-like Higgs event” seen so far was one in which (it is surmised) the proton-antiproton collision at the Tevatron had created a fireball which then decayed into a W boson (one of the carriers of the weak nuclear force) and a Higgs particle.

You too can do particle physics

This is just a heads-up for folks who are interested in particle physics and/or highly-distributed computing projects, like the well-known SETI@home.

You too can do particle physics

Public involvement in the Large Hadron Collider, a particle accelerator being built in Switzerland, has received a boost with the relaunch of the LHC@home project, which allows users to donate computer time for LHC computing projects.

Researchers hope the project will help them fine-tune the LHC to shed light on what dark matter is and why particles have mass.

More: here

As most readers undoubtedly know, there are quite a few distributed computing projects of this sort, in which anyone can participate. Examples include projects dealing with climate prediction, gravitational waves, protein folding, and Mersenne primes.

For more information, see the Wikipedia articles on distributed computing and the list of distributed computing projects.

Tags: LHC@home, distributed computing