Is it possible to travel through space and time in absinthe?



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Let's talk about wormholes. Perhaps you have heard them called "mole caves". As you call it, you will not be discouraged. In short, it is a topological feature of space and time that forms a kind of tunnel. It can associate different places in the same curved space or become a bridge between two spaces (other universes, other dimensions, and so on).

It is important to remember that such a characteristic – only hypothetical and the existence of earthworm holes experimentally or empirically, to observe, has proved to be unsuccessful so far. And this is the concept of such a peculiarity in the general theory of relativity. The soft caves were first spoken in 1916 (when the theory of white holes was raised), and in 1935 the caves of the caves were used. Albert Einstein and Nathan Rozen developed this idea.

Anatomy KirmgrauÅžu

Although these are hypothetical objects, their "anatomy" has been thoroughly investigated by scientists. The wormholes have two mouths. These are circular openings that serve as entrance and exit for travelers. They are connected by a "throat", that is, the tuner that connects two parts of the cosmic space.

Einstein was able to prove the existence of wormholes, but only with mathematical calculations. The models show that this tunnel must be filled with exotic matter with an energy density with a minus sign. Only in such circumstances can the wormhole be functional because it would create a powerful gravitational pull and prevent the closure of wormholes.

The general theory of relativity does not prevent the existence of such tunnels. It is assumed that the mouth of the wormhole could be a black hole. However, this must be an unusual black hole. Do not think that the collapse of all dying stars will create a future wormhole.

Is it possible to travel through absinthe?

Stephen Hawking was convinced that people could not use wormholes because of their instability.

In science fiction, wormholes are used as quickly as possible, as they can quickly overcome enormous distances or travel to other universes or dimensions. However, in reality, the use of wormholes is far more complicated than we think.

First of all, size is the problem. According to the researchers, the primary wormholes are microscopic and can not exceed ~ 30 cm. It would be difficult to find these tunnels and the spacecraft would not fit there. However, there is an assumption that the wormholes have been stretched by extensions of the universe.

It is difficult to determine the stability of a particular wormhole. Theoretically, they are divided into transitions and non-transferable. And these (like the wormholes of Schwarzhild, also called the Einstein-Rosen Bridge) collapse too quickly. Having this stable and remaining open for a long time will require exotic matter.

There is also suspicion that adding normal material (spacecraft, people, etc.) will cause the tunnel to collapse or collapse. But scientists do not neglect this topic because these wormholes would be very useful as a tool to explore the Universe.

Stephen Hawking was convinced that people would not be able to use wormholes because of their instability. However, some scientists believe that with the proper knowledge, these tunnels can be managed. In addition, earthworm holes can connect not only areas of space-time or two universes, but also become a certain time machine.

Two interrelated news came from Harvard's in- vestment. The newly calculated physicist Daniel Jafferis was able to base the existence of hypothetical shorter paths in the space-time tissue – "wormholes" – in the real universe. And immediately came to the conclusion that they were not suitable for travel.

"From an outside observer's point of view, movement through a wormhole will be tantamount to quantum teleportation using a pair of attached black holes," explains Jafferis. The basis for his calculations is the Einstein-Rosen Bridge concept, but he used modern quantum-effect calculation tools for analysis. He was able to model a situation where the first "untransferable" wormhole became a transition. At least in part.

Jafferis's calculations have shown that, under certain conditions, JS information can be obtained by transmitting them to light. It is not the same as a journey between a pair of JSs that make up a couple of wormholes, but opens up new directions for quantum mechanics, gravity, and unexplored physics.

However, a conclusion can now be made – the way through such a space-time structure will be heavy and long. It is so heavy and long that it is even more economically advantageous not to build a protective capsule for the rabbit in a black hole but simply cast a star ship caravan that will fly to the target at its fastest speed. They are very likely to reach the target much faster than the spacecraft through the mole.

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