Gravitational waves and quantum models.

 Gravitational waves and quantum models. 

Gravitational waves are a wave movement or radiation. That moves gravitational fields. The problem with gravitational waves is how they can pull particles into the gravitational center. The answer can be that small strings can form those gravitational waves. Those small strings can spin in one direction, and that thing drives fields that the gravity wave penetrates to the gravity center. There is also a possibility that if the superstring theory is right, the waves or small skyrmions that travel at the superstring’s shell push those particles to the gravitational centers. Which one is the correct answer? 

That depends on the gravitational wave or wave structure’s position. If those waves are horizontally crossing the object, those strings can push fields through that structure that could look like a little bit of an egg cutter, where wires cut the egg in bites. In the second model, the string goes lengthwise through the object. In that case, when a black hole or the gravity center sends a gravity wave, it evaporates. In that case, the structure that evaporates pulls those strings into it. 

The gravity wave itself is like an energy ditch. That travels in space-time. The energy ditch forms when the G-(Gravity)field travels through other energy fields. That gravity field takes other fields with it. So the idea is similar to how some strings travel through the wave. If the string goes through the wave in the opposite direction, it pulls the wave energy into it. And if there is enough time, that string will turn wave backward. The gravity wave is a ditch in the energy field that travels to the gravity center. 

That makes energy travel faster to the gravity center. So how can energy travel in the wrong direction? The gravity wave is actually a stronger point in the gravity field. When the gravity center pulls other fields around it. Those fields pull particles with them. A gravitational wave is a space-time phenomenon. That which the field travels faster or carries particles stronger than otherwise. Or actually, gravity is waves. And gravity waves travel all the time across the universe. But sensors see only the strongest gravity waves. Those waves form when black holes collide. 

The Answer is in the field interaction. Every single fundamental interaction (electromagnetism, weak nuclear force, strong nuclear force, gravity) is a wave movement. Otherwise, we can say that each fundamental interaction is like radiation. Every fundamental interaction has a unique wavelength in that radiation, or wave movement. So, when the black hole, or some other gravity center, sends gravity waves, it sends G-field waves. When those waves push the gravity field away. That causes the effect that other energy fields try to fill that hole. This thing causes an effect that we call gravity.