When did entropy start?

"An ordered, stable system of particles represents a low-entropy state, whereas a more randomized, energetic system of those same particles is a higher entropy state. Even though the entropy of nearly all systems always increases, that doesn't mean that the entropy of the Universe was initially zero, or even close to it." (BigThink, Did the Universe have zero entropy when it first began?) The lack of entropy makes the particle's movement in the system is harmonic. That means there are no pockets where the system can deliver its energy. 

Many researchers think that there was no entropy at the universe's beginning. That means all material and energy were in nice order, and that thing means that. There was no disorder or uncertainty in the system. At that point, we must realize that the scale in the system is the thing that we use to compare the scale of the entropy. That means the entropy can be large-scale in small systems and small-scale in large systems. When we think about the image that I took from BigThink.com, we can say that at the beginning the universe was in nice order when we look at it in the microscale. 

The thing. What makes entropy interesting is that homogenous systems where there is no internal entropy are more sensitive to outside effects than non-homogenous systems. The reason why glass is broken more easily than steel is that glass is a homogenous material. When something hits the glass, the pressure or energy starts to travel in it. And when one of the silicone atoms in the glass starts to oscillate.  

It transforms that oscillation into other silicone atoms. That causes a harmonic reaction, which pushes atoms away from each other and breaks chemical bonds. In steel, there are pockets where energy moves. When something hits steel. Iron transfers that movement into carbon. The lack of harmonic motion makes steel more tenacious than pure iron. 

And the thing that causes entropy is energy that falls between particles. There is more energy in pure iron. That falls between particles than in steel. In homogenous systems, the entirety pulls more energy in layers than in heterogeneous systems.  That energy causes more disorder between elements in homogenous structures. 

In that model the universe was in nice little layers there everything was homogenous. But in the macro scale, there was entropy. That means the universe had zero entropy when somebody looks at it vertically or from outside. But if somebody cuts the universe in two parts there is an onion-shaped structure. And a large scale there is uncertainty. That means entropy or uncertainty in the system can be numerically small, but its size can be dominant. 

The layers were entropic to each other. That means the different layers pushed each other away. Or vacuum at the outside of the structure pulled the upper layers away from the inner layers. And because the number of particles was not unlimited. There formed holes between particles. 

That caused their quantum fields to jump outwards forming the small standing waves or "quantum electric arcs". Those particles pushed against each other. And then there formed holes that pull structures from layers below them. The energy always travels from higher to lower energy levels. The hole at the upper structure pulls energy into it from the lower structure. That thing is devastating. When energy pushes particles away from each other there is more and more space between particles. And there falls more and more energy between those particles. 

When we think about particles, we can call them structures. There are always structures in the material. Even on the tiniest scale, there are structures like superstrings. Those superstrings are small bites of wave motion. The diameter and length of them are always different. And that forms empty points between them. That makes them oscillate. That movement releases free energy in the system. That means the material is like yarn balls. And if those yarn balls are in a vacuum that pulls the outer shell away. That thing forms pockets where internal superstrings transport energy which is the sub-wave movement. 

Increasing entropy destroys black holes. 

The mystery of gravitational waves is this: is their origin in particles or are those gravitational waves other wave subwaves? 

If we think that image again even the densiest objects have entropy. The reason for that is that the energy or radiation and particles do not affect it symmetrically. We can think that the black hole's gravity fields are like segments in a ball. The segment pulls material smaller, and the size of the black hole's nucleus turns bigger. In that model, there is a precise point in the black hole's nucleus where energy hits. And that causes asymmetry in energy production or energy release. Those impacts send wave movement through black holes. And that causes the effect called vaporization. 

We can see that vaporization as gravitational waves. The gravity wave's origin is in the oscillation in the black hole. When a black hole oscillates its event horizon changes its place. And when a black hole turns smaller it leaves very high energy particles and wave motion behind it. The main problem with gravity radiation is, does it comes from particles or straight from wave movement. In that model, the gravitational waves are the sub-waves. Whose origin is in another wave movement. 

https://bigthink.com/starts-with-a-bang/universe-zero-entropy/

https://en.wikipedia.org/wiki/Entropy