The black hole research from Finland opens new roads to light-photon-material interaction.

    The black hole research from Finland opens new roads to light-photon-material interaction.

When we talk about light or photon-material interaction we should name that thing as wave-particle interaction. Black holes are places where gravitation packs another wave movement in a very tight form. In a black hole, four fundamental interactions interact straight with each other. And in black holes, dark matter and dark energy interact with each other. 

When black holes form in the supernova explosions that explosion forms a vacuum. Then vacuum presses the material and wave movement to one entirety called sigularity. Massive gravity causes extremely powerful time dilation. And the singularity starts to travel in time. 

In this model time is a dimension. And the black hole is a hole in that dimension. The black hole forms a channel or tunnel through time. Past is at a higher energy level than future. The reason for that is the expansion of the universe. The energy that comes from the past pushes singularity to the future. That energy also keeps a black hole open. 

When the energy level rises the object jumps to the hill. Vaporization of the black hole makes the energy statue or energy hill look like a cone. The spin of a black hole forms a whirl that we see as an acceleration disk. The black hole itself is like a whirl. And when entropy or disorder increases in that system the black hole vaporizes. 

The black hole is like a shortcut through time. This is the thing that makes it so powerful. When an object falls into a black hole. It starts to travel in time because it cannot release its energy. We can use the water flow from the hill as an example of how material and energy travel in spacetime. The top of the hill is the top of the energy. And then the energy level decreases like a river flows on the slopes. During that journey, water delivers its energy to the ground. And that slows it's speed. 

"An artistic depiction of a wave encountering an exponentially curved spacetime. Credit: Matias Koivurova, University of Eastern Finland". (ScitechDaily.com/Physics Unraveled: Accelerating Waves and the Mysteries of Time and Relativity)

If we look at this image, we might understand why quantum-size black holes cannot pull material inside them. The superstrings would travel through those miniature black holes. The model of superstrings goes like this: the smallest part of the material is supersting. And particles are warped yarnballs of superstrings. Superstrings between particle and wave movement will transport energy out from the black hole. And they close the channel of the black hole. 

The black hole is like a tube that is drilled 90 degrees straight down from the hilltop. The speed of water that falls straight in this tube increases. The reason for that is that there is no friction between water and other material in the tube that is straight down from the hillside. 

In black holes material and wave movement cannot interact with outside. That means material and wave movement cannot release their energy. During the travel in a black hole. So when material travels out from a black hole it suddenly releases its energy. The thing is that. The vaporization of the black holes is seen in their radiation. The cone-shaped change in the shape of singularity may break some parts of the material. So in this model black hole is full of small white holes. Those white holes would be white hair. The cone travels in time, not in 3D space.  

But a white hole can used to travel through a black hole from the past to the future requiring that a black hole vaporizes in less than an attosecond. Then the energy that travels in a black hole should keep this structure open. Then if we can send craft through that cosmic light cable we must decrease its energy level very slowly. If that thing is not done material releases its energy so fast that it destroys it. 

The thing that destroys material is the fast energy flow out from particles. And that thing forms an electromagnetic vacuum or energy rips itself off the material. When energy travels out from the nucleus like a quark it causes interaction in the particle's quantum field. Decreasing the size of a particle causes a situation in which contact between it and its quantum field is lost. And that vacuum rips material in pieces. 

Can we transport information from the past to the future by using black holes? That thing is possible if at some point in black hole forms an energy level that is so high that is higher than the supernova that formed the black hole. Which side in the black hole is at a higher level determines the direction in which information travels. That means traveling back in time is possible but it requires a very high energy level. 

https://scitechdaily.com/physics-unraveled-accelerating-waves-and-the-mysteries-of-time-and-relativity/