When does harmony cause chaos?

Entropy in the system grows. And that thing destroys the system. In the black holes, entropy should be zero. In the superstring model, the black hole's singularity is an extremely smooth object. Even if the entropy in the system itself is zero. That doesn't mean that the system is infinite. Even the universe has limits. 

And entropy begins at the borders of the system. We can say that an extra system goes into the system. All systems form subsystems. The water molecules are subsystems of the ocean. And atoms are subsystems in the sun. The destructive system forms between subsystems and pushes them away from each other. This is why heat destroys quantum entanglement. It goes between superpositioned and entangled particles. And then the wire between those particles pushes them away. That third effect is the IR radiation that denies information travel between those particles. 

The outcoming quantum fields push a black hole in its form. And because the expansion of the universe makes outcoming quantum fields weaker the standing wave that pushes singularity into its form travels to a longer distance. The black hole requires that standing wave to resist the growth of the singularity. Without that wave, the singularity will vaporize or turn into energy. 

Heat destroys quantum entanglement, because it brings a third actor between those particles that are superpositioned and entangled. 

When we look at the waving structure we can see that the distance of particles changes. That movement pumps energy into the bonds. And sooner or later those bonds push particles away. 

The empty or vacuum pockets space in the system makes entropy possible. Those pockets allow particles in the system can start to oscillate. And then there forms standing waves that push particles away. Those pockets pull energy from large areas into them. And that causes a situation when energy that jumps away from the standing wave pushes particles away. 

That turns the quantum vacuum deeper around the singularity and sooner, or later the quantum vacuum pulls the superstring up from the singularity. That thing causes asymmetry in the quantum flow. Normally the singularity is absolutely smooth. And the ball-shaped quantum field around it is hard to break. Then that "hair" or the superstring acts like a needle that can push a hole into that ball-shaped quantum field. 

The entropy turns into chaos because energy can travel between those superstrings. The superstring's width depends on its energy level. And if some of those hollow superstrings bring energy out from the middle of singularity. That makes those superstrings thinner. That makes space between them. And sooner or later that energy from the quakes in the singularity. 

Energy does never hit an object fully symmetrically. When the energy beam hits the layer its sides are at a lower energy level than its center. The reason for that is energy travels out from the center of the beam to the side of the material. 

The energy beam pushes potholes into the material and then the energy that travels out from the energy beam sides will transfer energy horizontally to the material. That thing pushes those atoms or particles away from the energy beam. The side traveling energy creates a shadow to the opposite side of the particles and that pushes them sideways. 

"A model developed by evolutionary mathematicians in Canada and Europe shows that as cooperation becomes easier, it can unexpectedly break down. The researchers at the University of British Columbia and Hungarian Research Network used computational spatial models to arrange individuals from the two species on separate lattices facing one another. Credit: Christoph Hauert and György Szabó" (ScitechDaily, Nature’s Unexpected Rule: Too Much Harmony Can Lead to Chaos)

The thing that forms chaos is that the energy stress in the system is not fully symmetrical. When a black hole pulls stars and material in it. That effect forms the asymmetrical energy impulses that cause a release in the superstrings. When the other side of the system is at a higher energy level than the other. That thing causes a shockwave. And in the other side, the system is in the electromagnetic low pressure. In black holes, that thing is extreme because the black hole is so extreme phenomenon. 

Same way, pressure impulses do have not the same force in dense systems as in thin systems. The thin atmosphere has space where energy can go rather than in water. And that's why even small explosions in water are dangerous. In dense systems, the actor pushes more particles than in non-dense systems. And the black hole is the ultimate dense system. And all things that impact the system cause some kind of shockwave. A good example is when we hit the iron ball, we can move it. But there is also a wave inside that thing but the other effects cover it. 

So, the effect exists even if we cannot measure it. The thing that causes chaos is this: energy cannot ever affect systems fully homogenously. In all energy beams or energy effects, energy impact is strongest in the middle. When the energy effect hits the layer it makes a pothole. Then energy travels out from the beam from the sides and starts to push the pothole larger. That energy travels in a layer, pumping energy to the particles. That energy forms an electromagnetic shadow on the other side of the particle. And that pulls particles in the direction away from the energy beam. 

https://www.quantamagazine.org/computer-scientists-prove-that-heat-destroys-entanglement-20240828/

https://scitechdaily.com/natures-unexpected-rule-too-much-harmony-can-lead-to-chaos/