Use photons to simulate the journey through time
A team of researchers at the University of Queensland led by Dr. Martin Ringbauer successfully simulated time travel using the fundamental particles of light. According to Dr. Ringbauer, the team used photons to simulate the timeless movement of quantum particles and investigate their behavior. Through it, researchers have discovered many unexpected aspects in modern physics and provide an insight into the theory of the ability to perform time-based travel theory of theories. previous reason.
According to Dr. Ringbauer's argument: "The question of time travel still stands between the two most solid doctrines in physical history: Einstein's general theory of relativity and quantum mechanics theory. describing the world under the immense scale of stars and galaxies, while quantum mechanics is a great demonstration of the microcosm of atoms and molecules. "
The timeless structure uses horizontal and vertical lines to describe time and space axes.A photon will pass through the wormhole, move back in time and return to the same place in the original space.
Einstein's doctrine shows that it is possible to go back in time by following the space-time path to return to the beginning of space but to enter before closing the seam - before the space-time curve . In 1946, mathematician and mathematician Kurt Gödel proposed "imperfect theorem" and caused many physicists and philosophers a headache when placing it in relation to Einstein's doctrine.
Specifically, the "grandparents paradox" , if a traveler from the future returns to the past and prevents him and her from meeting, then the question is whether the time traveler will exist or not? This is what makes time travel completely unreasonable and impossible. However, a member of the team at the University of Queensland, physics professor Tim Ralph made a prediction in 1991 that time travel in the quantum world would be able to avoid generating inversions. physical.
Professor Ralph stated that there is no evidence that the natural world operates differently from the microcosm of quantum mechanical systems. However, this has not yet been verified in super-effects states according to the standards of general relativity, such as near black holes. According to Professor Ralph: "Our research provides an insight to answer where the question is and how it naturally behaves differently from what our theory predicts."
For example, research has shown the existence of gravity at the time of curvature of curved space. This implies reinforcing Heisenberg's uncertainty principle about changing the structure of quantum particles and forming another perfect replica under quantum angles to make time travel. As the first illustration illustrates a spacetime structure and a quantum particle can turn back time and then return to the same place in space through a wormhole.
In the end, the research of scientists at the University of Queensland is not about building a time machine. But this is a completely new approach in terms of quantum mechanics in search of arguments that support the feasibility of time travel. However, research has created a panoramic view and elicited a promising future of time travel done and controlled by people in the future.
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