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Semelhante a HIGG's BOSON - The 'GOD' Particle - Theerumalai Ga
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HIGG's BOSON - The 'GOD' Particle - Theerumalai Ga
- 2. The particles which gives MASS to other particles. It is one of the 17 particles of the standard model which makes the SM complete. If HIGG’s particles does not exist, according to the SM everything in the universe would be mass less. In the Standard Model, the Higgs particle is a boson with no spin, electric charge, or colour charge. It is also very unstable, decaying into other particles almost immediately. It is a quantum excitation of one of the four components of the Higgs field Found everywhere
- 3. Mass 125.09 (syst.) GeV/c2(CMS+ATLAS) Mean lifetime 1.56×10−22 s (predicted) Decays into bottom-antibottom pair (predicted) two W bosons (observed) two gluons (predicted) tau-antitau pair (predicted) two Z-bosons (observed) two photons (observed) various other decays (predicted) Electric charge 0 e Colour charge 0 Spin 0 (tentatively confirmed at 125 GeV)
- 4. Higg’s FIELD Affect Different Particles in Different WAYS PHOTONS Slide through unaffected W and Z Bosons Bogged Down with MASS Everything that has mass interacts with all Higg’s field As other fields on SM, Higg’s field also requires carrier particles Higg’s BOSONS BOSONS are particles responsible for all physical forces except GRAVITY
- 5. • Peter Higgs • Francois Englert • Robert Brout • Hagen • Kibble • Guralnik
- 7. On 4 July 2012, the discovery of a new particle with a mass between 125 and 127 GeV/c2 was announced; physicists suspected that it was the Higgs boson A Higgs boson of mass ≈125 GeV has been tentatively confirmed by CERN on 14 March 2013 Big Bang on a Small Scale By smashing protons together hard and fast enough, the LHC will cause protons to break apart into smaller atomic sub particles. These tiny sub particles are very unstable and only exist for a fraction of a second before decaying or recombining with other sub particles. But according to the Big Bang theory, all matter in the early universe consisted of these tiny sub particles. As the universe expanded and cooled, these particles combined to form larger particles like protons and neutrons.
- 8. 100 metre underground the border of FRANCE and SWITZERLAND 8 arc bounded sectors Circumference: 27 km 9600 magnets that can steer protons with 99.9% speed of light World’s largest machine examining the Universe’s tiniest particles About the Universe Matter and Anti matter String theory
- 9. ATLAS – A Torroidal LHC Apparatus CMS – Compact Muon Solenoid ALICE- A Large Ion Colloider Experiment TOTEM- Total Cross Section, Elastic Scattering and Diffraction Dissociation LHCb- LHC Beauty LHCf- LHC Forward MoEDAL- Monopole and Exotics Detector
- 10. ATLAS CMS
- 11. Answers questions about MASS How the Universe came into Existence Possibilities that we have more dimension Existence of MATTER , ANTI-MATTER and DARK MATTER Research on GOD particle developed other researches such as the LHC, communication system such as WWW and fields of research such as cloud computing. Eventhough the discovery of the GOD particle has no immediate technological benefits, the practical applications will follow later.
Notas do Editor
- The principle behind the LHC is pretty simple. First, you fire two beams of particles along two pathways, one going clockwise and the other going counterclockwise. You accelerate both beams to near the speed of light. Then, you direct both beams toward each other and watch what happens. When two protons collide, they break apart into even smaller particles. That includes subatomic particles called quarks and a mitigating force called gluon. Quarks are very unstable and will decay in a fraction of a second. The detectors collect information by tracking the path of subatomic particles. Then the detectors send data to a grid of computer systems.