Neoteo. Two physicists proposed a controversial theory that a strange kind of matter, the Higgs singlet, would move into the past or the future.
Besides being the largest scientific experiment in the world, the Large Hadron Collider (LHC) could become the first machine made by the man who would be able to make some exotic form of matter traveling backward or forward in time. Tom Weiler and Chui Man Ho, physicists from Vanderbilt University (Nashville, Tennessee), have surprised the world with a controversial theory that they claim does not violate any laws of physics or experimental limitations, assuming further that This is a very remote possibility. In fact, do not rule out that the LHC is already receiving some subtle signals generated by future experiments where a rare particle called the Higgs singlet is the main actor of this teorĂa.Uno of the main goals of the LHC is to find the elusive Higgs boson, the hypothetical particle that physicists call to explain why particles such as protons, neutrons and electrons have mass. If the collider succeeds in producing the Higgs boson, scientists predict that it will create a second particle, called Higgs Singlet at the same time. According to the theory proposed by Weiler and Ho, these jerseys will have the ability to jump to an extra dimension (fifth), which can be moved forward or backward in time and appear in the future or past. It would not go to people or objects, but perhaps to send messages to the past or the future, and also to receive, as suggested by the authors of the theory. One way to verify if this theory is correct is to analyze the results of the detectors to the hopes of any signal from any future experiment. On the other hand, the theory is responsible for specifying that only this kind of special particles have the property of "time travel" completely disregarding human beings. Weiler's theory is based on Ho and M theory, a theory of everything. " A small group of theoretical physicists has developed the M-theory to the point that it can adapt to the properties of subatomic particles and all the known forces, including including the weight, but requires 10 or 11 dimensions instead of the familiar four (three of space plus time). This has led some to suggest that our universe may be like a membrane (brane) floating in four-dimensional space-time multi-dimensional.
According to this view, the basic elements of our universe are permanently attached to the membrane and therefore can not travel in other dimensions. However, there are some exceptions. There are scientists who argue that gravity may be one of these, for example, because it is weaker than the other fundamental forces, and "dispersed" into other dimensions. Another possible exception is the proposal the Higgs singlet, which responds to gravity, but not any of the basic forces of physics.
Weiler began researching the possibility of traveling back in time six years ago to explain the anomalies that were observed in several experiments with neutrinos. Neutrinos are nicknamed "ghost" because they react very little with ordinary matter. Millions of neutrinos pass through our bodies every second without our knowledge of it and without affecting us. Weiler and colleagues Heinrich Pas and Sandip Pakvasa of the University of Hawaii approached an explanation of the neutrino anomalies in relying on the existence of a particle Sterile Neutrino hypothetical call. In theory, the sterile neutrinos are much less noticeable than regular neutrinos because they interact only with the gravitational force. As a result, sterile neutrinos are another particle that is not attached to the membrane above and also can be considered as able to travel through other dimensions. Thus, Weiler, PAS and Pakvasa proposed that sterile neutrinos could travel faster than light taking shortcuts through other dimensions. According to the theory of Einstein's General Relativity, there are certain conditions under which travel faster than the speed of light is tantamount to travel back in time. This led theoretical physicists to speculate on time travel. If Weiler and Ho are right with their new theory, the LHC could perhaps begin to pick up signals from other times that are not ours.
According to this view, the basic elements of our universe are permanently attached to the membrane and therefore can not travel in other dimensions. However, there are some exceptions. There are scientists who argue that gravity may be one of these, for example, because it is weaker than the other fundamental forces, and "dispersed" into other dimensions. Another possible exception is the proposal the Higgs singlet, which responds to gravity, but not any of the basic forces of physics.
Weiler began researching the possibility of traveling back in time six years ago to explain the anomalies that were observed in several experiments with neutrinos. Neutrinos are nicknamed "ghost" because they react very little with ordinary matter. Millions of neutrinos pass through our bodies every second without our knowledge of it and without affecting us. Weiler and colleagues Heinrich Pas and Sandip Pakvasa of the University of Hawaii approached an explanation of the neutrino anomalies in relying on the existence of a particle Sterile Neutrino hypothetical call. In theory, the sterile neutrinos are much less noticeable than regular neutrinos because they interact only with the gravitational force. As a result, sterile neutrinos are another particle that is not attached to the membrane above and also can be considered as able to travel through other dimensions. Thus, Weiler, PAS and Pakvasa proposed that sterile neutrinos could travel faster than light taking shortcuts through other dimensions. According to the theory of Einstein's General Relativity, there are certain conditions under which travel faster than the speed of light is tantamount to travel back in time. This led theoretical physicists to speculate on time travel. If Weiler and Ho are right with their new theory, the LHC could perhaps begin to pick up signals from other times that are not ours.
ABC Science.
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