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Bowles
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They say Higgs particles are so hard to detect because their mass is so big. But when their mass is so big, wouldn't that make them easier to detect?
Bowles said:But why the need of producing them? Don't they give all particles mass, so shouldn't they be ubiqious?
Bowles said:ahh, this virtual versus real particle business!
Keep forgetting and misunderstanding it.
So Higgs is sort of like the gluon field?
kdv said:In the sense that there is a quantum field associated to teh Higgs like there is a quantum field associated to the gluon, to the electron, to each quark, etc.
So this Higgs quantum field permeates space and the other fields interact with it yielding a mass for all the particles (the massive ones).
However, this is only indirect evidence. To have a direct evidence of teh Higgs field, we want to excite it and produce an observable excitation of the Higgs field which will appear as a Higgs particle. Until we produce and observe an excitation of teh Higgs field we won't know it if really exists or if maybe the particle masses are produced by an entirely different process.
Bowles said:I also like to add one question!
What particles are they smashing at another to get Higgs particle?
malawi_glenn said:Higgs boson is the particle that gives other particle mass, by mediating between the Higgs field and the other fields. Rough speaking. There are also a varaity of models, with different Higgs bosons etc.
The basic thing one wants to detect is the decay of the (real) higgs boson. A Higgs boson are belived to be created in the proton + anti_proton annihilation at LHC.
Parlyne said:Last I checked, the LHC is a proton/proton collider.
Rade said:fyi, the LHC will also investigate photon-photon interactions--see here:
http://arxiv.org/abs/hep-ph/0702212
and photon-nucleus interactions--see here:
http://arxiv.org/abs/0706.3356
Jim Kata said:My question about the Higgs, is why haven't they found it. I mean its mass is < 225 GeV,
and a lot of the GUTS place it's value a lot smaller. I've seen it being possibly as light as
115 GeV.
Coin said:As I understand things there are people who work on the Tevatron who are actually convinced that the Tevatron is already producing/can produce Higgs Bosons, but that the events are lost among the background noise. If this is true then the Tevatron actually potentially could find the Higgs before the LHC does, but it would be really really hard to do so successfully. Maybe once the LHC finds the Higgs and we know what to look for then we'll be able to see the Higgs resonances in the Tevatron data?
Coin said:As I understand things there are people who work on the Tevatron who are actually convinced that the Tevatron is already producing/can produce Higgs Bosons, but that the events are lost among the background noise. If this is true then the Tevatron actually potentially could find the Higgs before the LHC does, but it would be really really hard to do so successfully. Maybe once the LHC finds the Higgs and we know what to look for then we'll be able to see the Higgs resonances in the Tevatron data?
Higgs particles are elementary particles that are theorized to give other particles their mass. They were first proposed by physicist Peter Higgs and were later discovered in 2012 by the Large Hadron Collider at CERN.
Higgs particles are important because they provide a mechanism for particles to have mass, which is a fundamental property in our understanding of the universe. Their discovery also confirmed the validity of the Standard Model of particle physics.
The mass of a Higgs particle is estimated to be around 125 GeV (gigaelectronvolts), which is about 133 times the mass of a proton.
Higgs particles are detected by observing the decay products of collisions between protons in the Large Hadron Collider. These collisions produce a variety of particles, including Higgs particles, which can be identified by their unique decay patterns.
One of the biggest challenges in detecting Higgs particles is their short lifespan. They decay almost immediately after being produced, so scientists have to rely on indirect methods to detect their presence. Additionally, Higgs particles are produced in very small amounts, making it difficult to distinguish them from other particles produced in collisions.