Can we ever complete TOE (Theory of Everything)?

 Can we ever complete TOE (Theory of Everything)? 

TOE (Theory of everything) 

Can we someday make a collective theory that closes all other physics and quantum theories inside it? That is a really good question. TOE (Theory of Everything) is much more complicated than MOND (Modified Newtonian dynamics). 

That complicated thing means that in TOE researchers must interconnect fundamental particles and fundamental interactions into one entirety. That is the thing that makes TOE so interesting. The route from iron wire models to theories is long. And maybe we ever see the final version of TOE. 

The key element in TOE is that all fundamental particles or elementary particles are the same particle. The energy level of an elementary particle determines its shape. So Higgs Boson just turns to the Top Quark and then to another Quark. And there is a possibility that the Higgs boson is very close to the hypothetical chameleon particle. 

Chameleon particles are hypothetical actors that can change their shape from boson to fermion and the opposite. Fermions are elementary particles that form atoms. And bosons are transmitter particles for four fundamental interactions. So what if some particle can jump between boson and fermion states? 

"The Clebsch cubic is an example of a kind of geometric object called an algebraic variety. A classical result of enumerative geometry states that there are exactly 27 straight lines that lie entirely on this surface." (Wikipedia/ String Theory)

String theory and graviton. 

In string theory, the material is explained as a string. The string is like a hula hoop. Normally that hula hoop can turn into a ring-looking structure, and there is the possibility that this string will take absolute string form. When some electromagnetic radiation affects that ring it can form an extremely small black hole in the middle of it. Maybe that black hole can explain graviton the hypothetical source of gravitation. 

Those strings in string theory are quantum skyrmions. There are different size strings. And that thing means that when those strings impact each other that increases their mass. 

There is the possibility that at least some parts of so-called dark matter are gluons that orbit electrons. Or there is a theoretical possibility that gluons can start orbit quarks that are away from protons and neutrons. Proving that thing is difficult. And if some gluons and quark-pairs are interacting like protons and electrons in hydrogen atoms that is the fundamental thing. 

If there is a particle called gluon-quark that means it's hypothetically possible that this material is possible. The gluon-quark is the hypothetical chameleon particle that has the abilities of fermions and bosons. That hypothetical boson-fermion tensor could transform a boson into a fermion. 

But can we begin with electromagnetism? 

Why iron is magnetic? Iron is the least energy element in the universe. That means iron atoms turn very easily in the same direction. The magnetic field turns iron atoms in the direction where the S pole of the first iron atom is against the N pole of the second iron atom. That thing causes a magnetic field in iron. 

But in neutron stars, neutrons are also in the same way. The first neutron's N pole is against the other neutron's S pole. That means a neutron star is full of small generators that make an extremely strong magnetic field. Neutron forming of three quarks. One up and two down quarks. 

When neutron spins very fast it makes those three quarks act like harps. The distance between down quarks increases. The spin of up quark is stronger than others. So it pulls energy from those two down quarks. And then that up quark sends a photon. That interaction causes a pulling effect below those two down quarks. That pulling effect forms because of electromagnetic low pressure under those two quarks. 

Because gravitation is wave movement that means gravitation is radiation with a certain wavelength. And that causes the hypothesis that all wavelengths of radiation can change to another. That means visible light could turn to gravitational radiation. The neutron stars are sending also neutron radiation that is very high energy deep penetrating radiation. 

This makes those neutrons pull quantum fields through their structures. And that thing forms an extremely strong gravitational field. The black holes have a similar effect as neutron stars. But there is a transformer, the particle that changes all radiation into gravitational radiation. This is one of the most interesting things in the world. 

Droplet as a gravitational model. 

When the energy level of particles rises too high, that thing causes a situation in which the particle turns so small that it drops away from the universe. That thing is the black hole. Radiation that comes out from a black hole keeps it open. And that radiation just causes a similar situation as a droplet that drops on water. The first droplet pushes water away from it. 

And then water returns to the middle point forming a water statue. When black holes form in the supernova that thing pushes the quantum field away from it. We can think that gravitational waves have extremely short wavelengths and cycles. So the supernova pushes those gravitational waves away like a plate. That causes an effect where a supernova affects long distances in a very short moment. 

The gravitational fields are also quantum fields. When extremely high energy radiation impulse pushes gravitational fields away, that forms a structure that looks like a plate. And when eruption ends the gravitational- and other quantum fields start to drop into the middle of a black hole. There they reflect from the nucleus or singularity. So black hole transforms other radiation wavelengths into gravitational wave wavelengths. 

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

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

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

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

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