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This is necessary because the muons produce only very little light.
A muon is 207 times more massive then an electron.
Yet the muons are formed many miles high in the atmosphere.
A beam rate of a few hundred muons per second is expected.
In fact, a muon can become a much lighter electron.
Other than that, muons and electrons are essentially the same.
But it was giving off a continuous stream of muons.
A muon will only last a few seconds before becoming an electron.
But that's the way it looks to the muon.
The muons are implanted into the sample of interest where they lose energy very quickly.
However, later experiments showed that the muon did not participate in strong interactions.
The muon is a particle like the electron, only some 210 times heavier.
The muon has an average life time of 2.2 micro-seconds or 0.0000022 seconds.
The muons of the second generation were discovered in cosmic rays.
To us, the distance seems to be many miles, so why is it we see the muon make it?
Muons are unstable particles but they live long enough to leave the detector.
High energy muons are quite rare and a good sign of interesting collisions.
At first, the speeds of muons and neutrinos were compared.
This is how the muons and neutrinos are produced in the air shower.
And interestingly enough, there's a very tiny elementary particle called a muon.
So, all muons decay to at least an electron, and two neutrinos.
The 35 ton prototype is set up over ground to track cosmic muons.
Low energy muons and protons, invisible in water, can be detected.
For example, if the detected muon came from below, it would have to be neutrino-induced.
Although the neutrinos are invisible, they can create a different particle, a muon, in water.