Quantum entanglement driving wormholes
One of the strange conclusions of quantum theory is what happens when the pairing of elementary particles is created. These personal expenses entangled with them. As a result, other interactions with one of these particles have direct consequences, even if other particles are on the other side of the universe. The simplest examples are electrons and positrons, when photons interact with crystals when they are created. These particles are intertwined with each other and will continue to do so until one or the other interacts. This is also true even if one of the particles picks up the distant area of ​​the universe. One of the particles should be a photon with light, and said that in the "up" direction has been aligned with the spin, the other particles will have a spin alignment in the direction of the "down" moment. At first glance, this seems to be a violation of general theory of relativity, because information is forbidden faster than light. How can the spin information of the first particle be transmitted to its partners, potentially millions of light years away, without a minute or two passing? This problem plagued Einstein as well, and it was known as a ghostly superposition. Now, the researcher Andreas Karch came from Washington and the State University of New York at Stony Brook University in New York at the Jensen University of Jensen to solve the problem: Wormhole. These theoretical predictions of general relativity are generally related to black holes, where rotation and strong gravitational forces can distort the temporal and spatial extent. Entangled black hole pairs can establish a bridge from one object to the other. However, without the presence of foreign substances - such as particles that have never been observed with negative masses - there is no way to maintain the bridge, without its collapse itself. As a result, in the case of black holes, no information can be exchanged between tangled black holes. Karch and Jensen's work has demonstrated that the same wormhole solution can be reached instead of using general-purpose relativity in quantum mechanics. Now they argue that with the same kind of bridge, the link entangled the black hole to connect the pairs of quantum particles. Although there is still a lot of work to be done, this discovery will provide researchers with new tools to develop mechanisms for entanglement systems, whether they are massive black holes or quantum dots. Electronic Chemicals,99.8% Cas 7553-56-2,Iodine Crystal 99.8% Cas 7553-56-2,Iodine Crystal 99.8% Henan Tianfu Chemical Co.,Ltd , https://www.tianfuchem.com