http://blogs.discovermagazine.com/80beats/2010/07/27/new-revelations-from-particle-colliders-past-present-future/ Mon, 22 Apr 2013 21:34:00 +0000 hourly 1 http://wordpress.org/?v=3.4.2 http://blogs.discovermagazine.com/80beats/2010/07/27/new-revelations-from-particle-colliders-past-present-future/#comment-20882 Tom Croley Mon, 15 Nov 2010 22:48:00 +0000 http://blogs.discovermagazine.com/80beats/?p=18077#comment-20882 I don't think that smashing something together at high speeds and studying what flies off of the collision is an accurate method of discovering how things are really put together. Could you discover how a car is made by watching two cars smash head on at high speeds? If you smashed them enough times, you would observe certain repeatable phenomena like certain parts that always fly off the same way at certain speeds. But the whole process would not reveal the true engineering that went into the car. If fact, it may lead to some false conclusions as some parts fuse together at higher speeds and other parts disintegrate that would not normally do so at lower speeds. For this reason, this aspect of physics will always be a matter of speculation. I don’t think that smashing something together at high speeds and studying what flies off of the collision is an accurate method of discovering how things are really put together. Could you discover how a car is made by watching two cars smash head on at high speeds? If you smashed them enough times, you would observe certain repeatable phenomena like certain parts that always fly off the same way at certain speeds. But the whole process would not reveal the true engineering that went into the car. If fact, it may lead to some false conclusions as some parts fuse together at higher speeds and other parts disintegrate that would not normally do so at lower speeds. For this reason, this aspect of physics will always be a matter of speculation.

]]> http://blogs.discovermagazine.com/80beats/2010/07/27/new-revelations-from-particle-colliders-past-present-future/#comment-20881 Sylwester Kornowski Thu, 29 Jul 2010 09:10:48 +0000 http://blogs.discovermagazine.com/80beats/?p=18077#comment-20881 The Higgs boson(s) and Higgs mechanism are not in existence. Particles acquire their masses due to the internal structure and properties of the Einstein spacetime. The Einstein spacetime is a gas composed of the non-rotating binary systems of neutrinos. Photons are the excitations of local Einstein spacetime – they are the rotational energies of the binary systems of neutrinos. The Planck time is typical for the lifetime in excited state i.e. in state when the binary systems of neutrinos rotate. It causes that energy (a photon) disappears in one place of the Einstein spacetime and appears in another one and so on – in such way behave the quantum particles. It is very difficult to detect the non-rotating binary systems of neutrinos because they cannot transfer energy to a detector. Particles having mass consist of the bound binary systems of neutrinos. Their mean mass density is higher than the Einstein spacetime due to the possible phase transitions. Relativistic mass is due to the law of conservation of spin. Properties of the Einstein spacetime follow from the properties of the more fundamental Newtonian spacetime – it is gas composed of tachyons having positive mass. We can describe the whole matter and energy applying only seven parameters describing the Newtonian (6) and Einstein (1) spacetimes. These seven parameters lead to the physical constants and mathematical constants applied in physics. The Higgs boson(s) and Higgs mechanism are not in existence. Particles acquire their masses due to the internal structure and properties of the Einstein spacetime. The Einstein spacetime is a gas composed of the non-rotating binary systems of neutrinos. Photons are the excitations of local Einstein spacetime – they are the rotational energies of the binary systems of neutrinos. The Planck time is typical for the lifetime in excited state i.e. in state when the binary systems of neutrinos rotate. It causes that energy (a photon) disappears in one place of the Einstein spacetime and appears in another one and so on – in such way behave the quantum particles. It is very difficult to detect the non-rotating binary systems of neutrinos because they cannot transfer energy to a detector. Particles having mass consist of the bound binary systems of neutrinos. Their mean mass density is higher than the Einstein spacetime due to the possible phase transitions. Relativistic mass is due to the law of conservation of spin. Properties of the Einstein spacetime follow from the properties of the more fundamental Newtonian spacetime – it is gas composed of tachyons having positive mass. We can describe the whole matter and energy applying only seven parameters describing the Newtonian (6) and Einstein (1) spacetimes. These seven parameters lead to the physical constants and mathematical constants applied in physics.

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