, Wormholes and Whiteholes . Now let's mix them let's see what if a black Hole fall into a worm hole .
If wormholes exist, they could swallow black holes.
Astronomers think that they can see black holes falling on the palms using ripples in space known as gravitational waves, but only when the wormholes are present and such a phenomenon has occurred, a new study finds.
According to Einstein, who began predicting the presence of gravitational waves in 1916, gravity came from the path of space and time. When two or more objects move inside the magnetic field, they produce gravitational waves that travel at light speed, simplifying and compressing space time along the way.
Gravity waves are very difficult to detect because they are so weak, and Einstein was not sure if they really existed or if they would be found. After decades of operation, scientists reported the first direct evidence of the 2016 magnetic field, found using the Laser Interferometer Gravitational-Wave Observatory (LIGO).
Black holes vs. wormholes
Magnetic field observatories have detected more than 20 major collisions between extremely dense objects and large objects such as black holes and neutron stars. However, more unusual objects may be present, such as embryos, the collision of which should produce gravitational signals that scientists can detect.
Worms are tunnels in space, which, basically, can allow you to move anywhere in space and time, or go anywhere else. Einstein's theory of relativism allows for the existence of embryos, even if they really exist.
In fact, all the embryos are unstable, closing their opening. The only way to keep them open and to deal with is the type of exotic story called "mass negative." Such an exotic story has strange features, including flying away from gravity instead of falling into it as a normal story. No one really knows if this exotic story really exists.
No escape
In computer models, researchers have analyzed the link between a five-dimensional black hole and a transient stable caterpillar 200 times the mass of the sun with a throat 60 times wider than a black hole. Models have suggested that gravity signals unlike any seen so far will occur when a black hole enters and exits the caterpillar.
When the two black holes are close together, space speeds increase, much like spinning skaters bringing their arms closer to their bodies. Next, the frequency of the gravitational waves rises. The sound of these gravitational waves can produce tears, very similar to the time when a person quickly raises his voice at a slide, for any increase in frequency is similar to that of sound.
If one looked at a black hole creeping into a human tree, one could see a cry similar to the merging of two black holes, but the sign of gravity from the black hole would soon disappear as we released most of its gravitational waves on the other side of the caterpillar. (In contrast, when two black holes hit each other, the result is a huge explosion of gravity.)
If one looked at the black hole coming out of the worm, one would see "anti-chirp." Specifically, the frequency of gravitational waves from the black hole will decrease as it moves away from the caterpillar.
As the black hole keeps coming in and out of each wormhole's mouth, it would produce a ringing cycle and anti-chirps. The length of time between each chirp and the anti-chirp can decrease over time until a black hole is stuck in the larvae's throat. Finding this type of gravitational signal may support the presence of worms.
"Even though the caterpillars are very speculative, very speculative, the fact that we can have the power to prove or at least give credence to their existence, is very good," co-author William Gabella, a naturalist at Vanderbilt University in Nashville, told Space. com.
In this case, the black hole would eventually stop coming in and out without the worm and stay close to its throat. The consequences of such a conclusion depend on the preconceived notions of the exotic story found in the caterpillar's throat. Another possibility is that the black hole has successfully increased the size of the caterpillar and the caterpillar may not have enough external material to remain stable. Perhaps the disruption caused by space time caused the black hole to change its size into a force in the form of gravitational values, said Gabella.
As long as the caterpillar weighs more than any black hole it encounters, it should remain stable. If the caterpillar meets a larger black hole, the black hole can interfere with the larvae's function enough to damage the worm, cause it to collapse and possibly build a new black hole, Gabella said.
It remains uncertain what would happen if the black hole only crosses the edge of the caterpillar, part of the black hole enters the caterpillar's mouth and everyone else stays out of it. "I suspect there will be some crazy behavior at the black hole event that will lead to a lot of gravity and a lot of energy," Gabella said. Such a collision could also affect the fetus' case, "resulting in an unstable worm," he added.
Future research could explore the link between the wormhole and any common matter that enters the wormholes, as well as more complex conditions, such as the possibility of the wormhole's rotation, said by scientists . Other research clues may investigate how gravitational waves interact with a common and uncommon phenomenon in these situations, as well as "a variety of possible pathways between worms and name it," he added.
Images Source : Space.com
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