Harry Potter and Star Trek fans will always dream of it. Capt. James T. While in the universe of Kirk and Shree, Potter and his friends can travel through the magic of “phenomena”. Spock uses a machine to reconstruct a crew member’s DNA to be reassembled elsewhere as if the distance did not exist.
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Harry Potter and Star Trek fans will always dream of it. Capt. James T. While in the universe of Kirk and Shree, Potter and his friends can travel through the magic of “phenomena”. Spoke uses a machine to reconstruct a crew member’s DNA to be reassembled elsewhere as if the distance did not exist. Teleportation As it may seem, several experiments have been conducted in the last quarter of a century, indicating that the phenomenon is getting closer. In 1998, Professor Anton Seilinger of the University of Vienna succeeded in transferring a photon from one bank of the Danube to another. Twenty years later, a research team from the Quick Lab at Delft University of Technology (TU Delft) conducted an experiment and confirmed that quantum data can be teleported. She can connect two electrons that are separated from each other so that they share property with each other. Have you taken the first steps towards teleportation? Teleportation, as it appears in science fiction, begins with the idea that all information from an object can be collected at the subatomic level, and that information can be moved faster than light and the object can be reproduced elsewhere. “But in quantum theory, it’s a fundamental law that particles cannot move faster than light,” says Frank Verstrett, a professor of physics at the University of Ghent. The word fell: quantum theory. You need JavaScript enabled to view it. To enable teleportation, an object – or a person – must be decoded to that level. It is only in that discipline of physics that many laws that seem to contradict quantum theory appear to become almost a philosophical discipline. In fact, quantum physics is a kind of probability interpretation of reality in which every tiny particle is in a quantum state. It is a combination of variables such as particle motion position, direction, and velocity. For teleportation, you need to collect all the information about the quantum state of an object before sending it. However, according to another physical theory, the quantum state of an object cannot be fully determined. Physicists cite Heisenberg’s uncertainty relationship to this. In 1927, he described quantum mechanics as having pairs that could not be accurately recorded at the same time. In other words: if you determine the position of a particle accurately, the velocity will be uncertain. As an illustration, think of a dice. You have a one-sixth chance of rolling three. But you are less likely to roll three and roll something else. In quantum mechanics, it is possible for two particles to have several features that seem to be unique to each other at the same time. For example, quantum versions of quits and classical zeros, and versions of digital information and zeros may be one at the same time. If you transfer that thought from the subconscious level to the sensory world, you will reach Schrdinger’s cat. In that 1935 experimental experiment, a cat was locked in a box containing a radioactive atom, a Geiger counter, and a bottle of hydrocyanic acid. When the atom is depleted, the geiger hits the counter and shatters the bottle of hydrocyanic acid. If so, the cat is dead. If it does not expire, the cat will live. In quantum theory, a cat is dead and alive as long as you do not open the box to see if the atom is depleted. For Schrംഗdinger, that experiment was enough to conclude that quantum mechanics was only a theoretical model but not a description of the real world, in which a cat could not die and live at the same time. Quantum theory proves its usefulness for understanding small particles in physics. We now have the tools to experiment on an atomic level and see what Schrംഗdinger thought was impossible. For example, experiments at Delphi have shown that information about the position and direction of an electron can be transmitted through teleportation without change. “We did it without moving the electron itself,” says Livan van der Sipen, director of Flemish Scientific at Quake in Delft, and TNO, a Dutch organization and TNO at the Quantum Technology Institute. “In our experiments with teleportation of quantum information, there is an electron in both places. We only move information about the state of the electron.” It’s not easy. This first requires a trap of two electrons. Most importantly, a change in information occurs with two trapped electrons on one side, and immediately with the electron on the other. It is a multi-layered interaction. Suppose you toss a coin and write the result on two sheets of paper. You send one to another in New York and another to Los Angeles. No one knows what is in those envelopes, but if the result is with one coin, it will be the same as the other. The Enlightenment was first published in an essay by Albert Einstein in the 1930s. In it he found evidence that quantum mechanics was incomplete. In his opinion, there must be ghosts at work that can inextricably link two particles in different places, thereby sharing all their properties. By illuminating two electrons with the same laser beam and trapping them in the light they emit, the researchers at Delft show that complexity is indeed possible. In 2014, they did it at a distance of 3 meters, and four years later at a distance of 1.3 kilometers. QuickTouch testing is a step towards teleporting quantum information over long distances. Information can be moved at the speed of light via an optical cable. But if superfast internet is the only benefit, does teleportation make sense? “There are, of course, useful applications of that insight,” says Vandersipen. “We’re working here on a quantum version of the Internet in Delft. It’s not only about speed, but also about security. No one can pay attention or change without noticing, because if anyone tries to intercept a photon, it will affect the quantum state. Will it be more of a blockchain technology than a future application in space travel? Wanderersipan: “You can see the blockchain technology in parallel, because they both increase the security of the encryption, but the difference is that the blockchain starts with the notion that the most powerful computers can not break it, a quantum version depends on natural laws to ensure security. Quantum Internet hackers can not.”