A Factory of Quark Gluon Liquid
The graphic below gives an overview of the dangerous process LHC is undertaking. In the lower graph are the dates of production of different types of quark-gluon liquid at the LHC’s quark factory. They are presented in the estimated time frame according to energy levels and CERN’s schedule.
4th july update.
While the Higgs does not give mass to other particles – Einstein’s Relativity theory does with his principle of equivalence between mass, gravitation and acceleration (this is the big lie of nuclear physicists, which pumped up its importance to get funding going, as if politicians knew it was just another particle wouldn’t have funded the Higgsteria) – the Higgs complestes the triad of bosons, the W->Z->H, of increasing mass, which ‘break the symmetry’ of our electromagnetic space-time, converting it into the heavy quarks of the dark world (strange, bottom and top quaurks). So the dangers of creation of toplet or strangelet quark-gluon explosives will increase as CERN ramps up the LHC to reproduce more Goldstone bosons (aka Higgs). And now this chances have increased as to reproduce massive quantities of Goldstones has become the absolute goal of CERN after finding that boson. In the graph we can see how our world of electromagnetic matter can die (what physicists call ‘breaking its symmetry’) as those bosons convert our matter at an increasing rhythm with more energy ‘upgrades’. The fundamental events will happen after the 2015 upgrade, since the barrier of the dark world of strangelets toplets and Higgs/Goldstone ‘generators’ of dark matter is at 10 Tev.
The Large Hadron Collider is a factory of strong quarks, the hyper-massive particles inside the nuclei of atoms. The LHC is a 7 Tev, superfluid atomic cannon that collides head on, at light speed, Hadrons, the heaviest, stable atomic nuclei made of lead. It breaks their electro-weak cover, deconfining and massing together lead’s 621 quarks. Its aim is to create the quark gluon soup that causes all types of big-bangs and also creates super-novas. The danger is if the quark gluon soup becomes stable, it will absorb all the quarks of the planet and blow up the Earth, creating a super-nova.
Consider this video with some humor, in which the main scientists involved in the discovery of quark condensates, Mr. Gell-mann and Mr. Wilzeck explain how such quark gluon soup could be formed:
The LHC is a factory of the most dangerous substance of the cosmos, quark condensates.
The quark gluon soup is a far from equilibrium complex liquid; an ultradense, superfluid quark condensate, with 2 components, similar to a super-nova:
Inside it creates a superfluid vortex of strange quarks, a whirl of space-time that attracts inward the atoms that surround it, as a hurricane attracts objects towards its center. But the quark-gluon soup turns at light speed, like black holes do, so it is far more powerful. If it becomes stable it sucks in the mass of the Earth leaving a small quark star in the center as super-novas do.
As it cracks and liberates those quarks, it also creates a blast of radiation with our electro-weak cover (the substance of which our world is made). This wave is the hottest, most energetic radiation of the Universe, reaching 3 trillion degrees.
The simplest far from equilibrium system is a refrigerator: Inside it gets colder (similar to the superfluid vortex of quarks), because outside the radiator expels the heat out. A supernova is the most extreme far from equilibrium system of the Universe: inside the strange liquid (strangelet) gets colder near 0 K, because outside its gets so hot. Inside its cyclical vortex reaches c-speed (light-speed) because outside radiation blasts away at c-speed.
In the opening graph, in the upper side, we see the equivalent ultra-dense quark stars whose creation those types of quark-gluon liquid trigger. Since 99% of what the Large Hadron Collider will produce in its hadron collisions will be quark-gluon liquid NOT cosmic rays, the natural result of those collisions should be the conversion of the Earth in one of those 2 types of quark stars:
2009 –2015: Experiments at 3.5 – 4 Tev. Production of strange quark liquid (strangelets)
LHC’s production of strange quarks started at 1 Tev, the barrier of energy, beyond which our light, atomic matter dies (left, yellow line), breaking its symmetry and liberating its quarks. CERN produced an unexpected quantity of kaons and hyperons, the atoms of strange liquid. The production of increasing quantities of strange quark-gluon liquid will continue in 2011 and 2012 as the collider ramps up its energy to 3.5 Tev and multiplies its luminosity (density of collisions) with lead atoms
CERN said the probability of forming strange liquid, which detonates stars in mini big-bangs and supernovas, was minimal. This has been proved false. These first experiments had minimal energies where Kaons (u-s and u-d quarks) were massively produced. This has proved that the LHC will be a ‘factory’ of strange liquid, strangelets, made of up, down and strange (usd) quarks. At c-speed (light speed) our quarks will acquire relativistic mass becoming heavy strange quarks, forming massive quantities of usd quarks, hyperons, strangelet atoms. This will transform CERN into a factory of strange liquid, the Zyklon-gas that can destroy the Earth.
This astounding discovery, proved experimentally that the probability of a global holocaust is enormous. But CERN has no intention of halting its experiments. Its SS-authorities (Strange Science experts) will keep publishing detailed papers on the production of strangelets, which will keep falling to the center of the Earth. Earthquake activity, which is already now at its recorded maximum will increase till finally the strange liquid crunches the planet into a ball of quark matter. As in the case of Global Warming, experts paid by the company will continue to deny these facts.
est. 2015. Experiments at 7 Tev. Production of black holes with strings & top quarks.
We see in the base of the top quark triangle in the right side of the graphic, 2 massive quarks, the bottom and charm quarks, which should form a stable bcb dark atom, associated to a super-heavy electron, the tau electron. On top of that triangle we found the densest, heavier quark of the Universe, the top quark, which is produced by the decay of the Higgs into a top + antitop quark. Since the Higgs produces top/antitop quarks that in great numbers can condensate into toplet explosive liquid, those antitop/top quark-gluon liquid condensates will be likely produced in 2015. This toplet liquid is simply a much more powerful version of the strangelet liquid. Since Einstein affirmed black holes should be made of an ultradense ‘cut-off’ substance, calling them frozen stars, they are probably made of top quark condensate, the densest substance of the Universe. Further on Maldacena has proved that a classic black hole made of strings in 5 dimensions is equal to a black hole made of quark-gluon liquid in 4 dimensions. Consequently black hole, aka frozent toplet stars will likely form at CERN, est. 2015, when the LHC makes huge quantities of top and antitop quarks to manufacture the Higgs: t + t-=Higgs.