Effects 10,838 to 10,840.
Graceli effects on interactions, spreads, and violation of parities.
Neutrino interactions with Graceli energies and phenomena.
interactions of neutrinos () with protons, in a reaction of type:
(involving Z0). This same result was confirmed in 1974 (NuclearPhysics B73, page 1), by this same group of researchers led by Musset. It should be noted that an experiment related to charged leptonic current is of the type:, 
and that surrounds the W + particle.: [Ptemrldf]:, [Ptemrldf][Ptemrldf] = thermal potential, electric, magnetic, radioactive, luminescent, dynamic, and phenomena.
variations of energies deep inelastic scattering with energies and phenomena of Graceli [Ptemrldf].
the deep inelastic scattering of (e) polarized electrons obtained by means of an electron source (with energy between 16-21 GeV) specially constructed for this experiment. The scattering target was the protons (p) of heavy hydrogen (deuterium) from the bubble chamber
the energies of Graceli in interactions [cited above] and the potentials of the phenomena of Graceli. such as tunnels, entanglements, currents, conductivities, resistances, superconductivity, decays, entropies and enthalpies [electric, magnetic, thermal, luminescent, radioactive], electron and wave emissions, and others have direct action on the intensity of parity violation.
the violation of parity stems from the fact that the electrons were differently scattered by the target, spin spinning to the left, slightly more scattered than the spin electrons spinning to the right, in a ratio of 2 to 10,000 of each species. Taylor, assuming that there was an e-p electromagnetic interaction, the result indicated that there was a violation of parity conservation by an electromagnetic interaction, a result that was contrary to Quantum Electrodynamics (QED) (see entry in this section). series). Thus, Taylor concluded, the interaction mechanism of the reaction studied is that of weak interaction with neutral leptonic current, since no electric charge was exchanged between the electron and the proton. Therefore, it was an electroweak interaction according to TEFS-W. These experiments, therefore, confirmed the existence of the particles W +/- and Z0.
the W +/- and Z0 particles were finally discovered in 1983, as a result of the experiments carried out in the Super Proton Synchrotron (SPS) of CERN, due to the proton-antiproton collision (), under the leadership of Rubbia (Collaboration Underground Area 1 - UA1) , the French physicist Pierre Darriulat (n.1938) (UA2 Collaboration), thanks to the detection techniques invented by the Dutch engineer Simon van der Meer (n.1925; PNF, 1984), such as stochastic cooling, and the antiproton accumulators he developed between 1972 and 1976. Thus, leading a large team of scientists, notably Guido Petrucci and Jacques Gareyte, van der Meer managed to obtain beams of protons and antiprotons with 270 GeV of energy for each one their. Parallel to this, the detector known as the Multiwire Proportional Chamber (MWPC), invented by the Polish Frankish physicist Georges Charpak (n.1924; PNF, 1992), was also used in 1968 (Nuclear Instruments and Methods 62 ; 65, pp. 262; 217), with the collaboration of R. Bouclier, T. Bressani, J. Favier and C. Zupancic.
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