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aljo2345
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I am writing to propose an experiment to observe the physical affect on matter within the interior of Black Holes. The approach requires combining the phenomena of Quantum Entanglement with the manufacture of mini Black Holes in the CERN’s LHC (Large Hadron Collider): A paper by Choptuik and Pretorius, published on March 17, 2010 in Physical Review Letters, presented a computer-generated evidence that micro black holes could form from two colliding particles with sufficient energy, which might be allowable at the energies of the LHC if additional dimensions are present other than the customary four (three space, one time). Due to the unobservable nature of a black hole’s interior (and by extension any physical process that occur within it) I am proposing an indirect method of ascertaining the nature of a black hole’s interior by its influence on entangled matter. As you may already know, Quantum Entanglement is the effect where one object gets connected to another so that even if they are separated by large distances, an action performed on one will affect the other. Recently, physicists have succeeded in demonstrating that these quantum mechanical effects are not limited to the microscopic scale, but can be produced at the macro level (http://www.livescience.com/17264-quantum-entanglement-macroscopic-diamonds.html.). In future, perhaps, an experiment could be devised where one of a quantum entangled pair could be sent into an artificially produced black hole. In doing so, one could observe the effect on the other spatially separated but connected pair. Albert Einstein's theory of special relativity showed that energy has an equivalent mass, and mass has an equivalent energy. Further to this, the law of conservation of energy states that the energies in an isolated system is a constant; that energy may neither be created nor destroyed. Wouldn’t it be interesting to see what happened?