Authors: George Rajna
Now, for the first time, scientists at Stanford and SLAC have created a silicon chip that can accelerate electrons-albeit at a fraction of the velocity of that massive instrument-using an infrared laser to deliver, in less than a hair's width, the sort of energy boost that takes microwaves many feet.  The first full characterization measurement of an accelerator beam in six dimensions will advance the understanding and performance of current and planned accelerators around the world.  Researchers have found a way to accelerate antimatter in a 1000x smaller space than current accelerators, boosting the science of exotic particles.  THREE WEEKS AGO, upon sifting through the aftermath of their protonsmashing experiments, physicists working at the Large Hadron Collider reported an unusual bump in their signal: the signature of two photons simultaneously hitting a detector. Physicists identify particles by reading these signatures, which result from the decay of larger, unstable particles that form during high-energy collisions. It's how they discovered the Higgs boson back in 2012. But this time, they had no idea where the photons came from.  In 2012, a proposed observation of the Higgs boson was reported at the Large Hadron Collider in CERN. The observation has puzzled the physics community, as the mass of the observed particle, 125 GeV, looks lighter than the expected energy scale, about 1 TeV.  'In the new run, because of the highest-ever energies available at the LHC, we might finally create dark matter in the laboratory,' says Daniela. 'If dark matter is the lightest SUSY particle than we might discover many other SUSY particles, since SUSY predicts that every Standard Model particle has a SUSY counterpart.'  The problem is that there are several things the Standard Model is unable to explain, for example the dark matter that makes up a large part of the universe. Many particle physicists are therefore working on the development of new, more comprehensive models.  They might seem quite different, but both the Higgs boson and dark matter particles may have some similarities. The Higgs boson is thought to be the particle that gives matter its mass. And in the same vein, dark matter is thought to account for much of the 'missing mass' in galaxies in the universe. It may be that these mass-giving particles have more in common than was thought.  The magnetic induction creates a negative electric field, causing an electromagnetic inertia responsible for the relativistic mass change; it is the mysterious Higgs Field giving mass to the particles. The Planck Distribution Law of the electromagnetic oscillators explains the electron/proton mass rate by the diffraction patterns. The accelerating charges explain not only the Maxwell Equations and the Special Relativity, but the Heisenberg Uncertainty Relation, the wave particle duality and the electron's spin also, building the bridge between the Classical and Relativistic Quantum Theories. The self maintained electric potential of the accelerating charges equivalent with the General Relativity space-time curvature, and since it is true on the quantum level also, gives the base of the Quantum Gravity.
Comments: 20 Pages.
[v1] 2020-01-03 04:40:04
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