A huge galaxy ring challenges cosmology.

In the  Big Ring (in blue) and Giant Arc (in red) galaxies form a ring-shaped structure. There is the possibility that those megastructures look like corkscrews. If we would see that structure from another angle. Those megastructures formed around some kind of explosion or material eruption. And that model causes an idea that maybe the Big Bang was not a unique case in the Universe's history. 

If those galactic megastructure rings are forming shapes like corkscrews. That thing means that those structures are formed around the cosmic whirls. And maybe that thing can explain the Big Bang. Or that thing explains that there were some kind of whirls or internal anomalies in the shockwave that left from the Big Bang. But what formed those whirls? 

The Big Bang Theory formed a model where material started to escape from the Big Bang point symmetrically. The problem with symmetrically escaping material and energy is that. There will not form whirls. The quantum whirls are the things that formed the first particles. When the Big Bang happened, that thing caused a shockwave. Then some kind of effect caused turbulence in that shockwave. And that turbulence formed the wave-particle duality or Schwinger effect that turned wave movement into particles. 

The model is called wave-particle duality. Requires that there is some kind of impact or particle in the traveling quantum field. The Schwinger effect turns wave movement to particles when two wave fields are crossing. But that thing requires that something forms a whirl in the quantum field. Carefully thinking Schwinger effect turned wave movement into particle-antiparticle pairs. And then those particles impacted and formed annihilation. 

That kind of annihilation reaction or series of annihilations formed impacting waves, that could form material in the form as we know it. But in that model, there were a series of annihilations, that pulled energy levels down. The question is where the first disturbance came from. That formed those first primordial particles. Annihilation is a good model, but that requires that some particles can annihilate. And that requires the particle's existence. 

That means the Big Bang was a series of events. And maybe there was some material in the young universe. That is not possible in our universe. If we think of baryons that include one top and two bottom quarks, that particle is very short-living. But in the young and high-energy universe that material might exist in a very short time. 

And could the "primordial hydrogen" form of baryon that had two bottom and one top quark, and maybe muons could act as electrons for that material? The existence of that hypothetical material remained for a very short time. When the energy level in the universe decreased that primordial material vanished. 

https://www.bbc.com/news/science-environment-67950749

https://news.sky.com/story/amp/scientists-make-huge-discovery-that-challenges-our-understanding-of-the-universe-13046272

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

https://en.wikipedia.org/wiki/Wave%E2%80%93particle_duality