Why does higgs boson decay

The excess doesn't amount to much, Spiropulu told Live Science. Looking at the raw data, even with a trained eye, you might not think anything of it. But with the aid of machine-learning algorithms, the researchers showed that this tiny crop of unexplained muons has just a 0.

Physicists call that level of certainty that they've found a signal and not just noise "three sigma. Related: The 12 strangest objects in the universe.

Typically, a discovery isn't considered proven until it reaches "five sigma," equivalent to a 0. So Spiropulu was careful to say that a Higgs-muon coupling hasn't been proven yet.

That amounts to a 4. If more data pushes the confidence level to five sigma, Spiropulu said, it could help confirm an exponential relationship between the mass of a Higgs decay product and how often the boson decays into that particle.

Physicists believe that the frequency of the Higgs boson's decay into each particle it couples with can be predicted by the square of that particle's mass, so heavier particles turn up much more often. This finding could help prove that if the frequency matches the prediction. Spiropulu said that the LHC is now probably pushing the limits of its sensitivity in terms of detecting lighter Higgs decay products.

The collider certainly isn't powerful or sensitive enough to produce enough Higgs-electron decays for anyone to measure, for example. And it's nowhere near the level of equipment needed to measure coupling between the Higgs and ultralight neutrinos. Future detectors will have an advantage over the LHC, she said. The collider was built big and blunt, blasting protons at each other and covering a wide energy range, because physicists didn't yet know the mass of the Higgs — a critical detail for producing the particle.

Future colliders might be fine-tuned to the Higgs mass, and produce enough events to turn up even rarer couplings. And as the detectors get more sensitive, she said, they may turn up discrepancies with the Standard Model, leading the way toward new physics ideas.

Live Science. Rafi Letzter. See all comments Can anyone point in the direction of the universe where the Big Bang occurred? Is it possible people created a Higgs muon that started motion in the universe? If motion first started on earth, it would explain why the cosmic red shift points to the earth at the center of the universe, maybe because motion first started here?

Could people have started motion in the universe by generating a particle that allegedly went faster than the speed of light? Was this the time the universe started to fall expand into another static gravity field past the microwave background?

When was the last time the universe was at 2 Kelvin? When did Motion Start? When did motion first start? Science knows the formation of matter in our universe was caused by the forces of the universe. The paradox would be, what force could cause motion to begin, without moving in its present space-time? The Gravitational Cosmological Theory was developed from an is rooted in the Einstein Steady State Theory and the Bondi-Gold-Hoyle Steady State Theory, Wherein the Steady State Theory the universe, contains more protons than electrons that create dust particles and galaxies formed in their current locations and the cosmic matter is recycled therein at the center of the galaxy furnace.

The Theory: 1 The expansion of the universe is a result of the " heat ' contained therein; 2 The source of the " heat " is the cosmic microwave radiation background at 3 Kelvin, wherein; 3 The microwave electro magnetic-nuclear energy was formed as a result of the interaction of two different static gravitational vacuum fields, Helium 2 and Helium 4 gravity? A lot of background "noise" results from this process, and b quarks "are almost impossible to tease out from background" "fuzz," or sprays of lighter particles known as jets, Beacham said.

Additionally, ATLAS and CMS are separate detectors, so the collaborations working on each one must make and confirm these observations separately for it to "count. The findings are another big step along the journey to better understand the Higgs boson and our universe. And each new discovery or observation, like the discovery of the Higgs boson, has the potential to give way to new questions and experiments.

Observing this decay mode also leaves less room for potential undiscovered particles to contribute to fermion masses. In confirming that this particle does, in fact, decay into b quarks, these physicists have shown that the Higgs field, the field behind Higgs boson particles described by Beacham as the "invisible jelly that permeates all of space," gives b quarks mass. The Higgs field uses the Higgs boson to interact with other particles, like the b quark, and give them mass.

Experiments like these allow physicists to not only validate what the Standard Model predicts about the Higgs boson and b quarks but also challenge what the Standard Model predicts.

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