What was before the Big Bang?

“Our entire cosmic history is theoretically well-understood, but difficult to depict in a static, 2D image. The Universe’s present expansion rate and energy composition are related, which is why most modern illustrations of our cosmic history have a tube-like shape: where they often (dubiously) depict an initial singularity, a period of inflation, and then a slower expansion that changes with time while our Universe evolves. No one diagram encodes all of these details correctly, including the one shown here, which seems to maintain a constant “size” for the Universe, disagreeing with reality.” (BigThink. The strongest evidence for a Universe before the Big Bang)

Can the source of dark energy be in particles that go out from the universe and evaporate in that extremely low-energy place? When a particle or black hole travels out of the universe. The outside quantum field cannot keep the particle in its form. In the universe, the outside energy field presses the particle. And slows its energy transfer to its environment. Particles are condensed versions of energy. And when those particles release their energy very fast, that means they turn into a wave movement. And if the energy level around them is zero, that means those particles detonate. They send those waves into the universe. But they send waves that also impact outside the universe. 

Even before the Big Bang, the universe or spacetime was not really empty. There were fields and wave movement. That formed material and the universe where we live. The big question has always been where those waves and fields came from. Also, those fields. Must have some kind of source. 

The fact is that matter cannot form from emptiness. So there must be some kind of wave movement. And one suggestion is that. There were gravity waves before the Big Bang. Or the event that formed our universe. But was there a universe before our universe? This question remains open. The thing that we call the universe is a structure. Where matter and energy have a certain form or shape. And that means we should ask if there was a structure before our universe, where matter and energy had similar shapes, as they have in our universe, or the universe where we live. The new model goes like this. The gravity waves that were the only existing thing before our universe started to form were impacted and started to condense into gravitons. And then those gravitons could form the massive kugelblitz black hole, which detonated. That could even look like a series of explosions, because when that massive object released its outermost shell, its size increased. 

At that point, the gravity waves that this object sent pushed other gravity waves away. When we think about that very first black hole, we must remember that this object formed in a very different universe than the one we live in. That object was the only gravity center in the universe. And that means its effect was larger scale than the gravity centers have in the modern universe. When we think about the first magnetic fields. They were not more powerful than the human EEG; we must remember. That energy level is always relative to its environment. The universe was very hot and dense, and those electromagnetic fields formed into a place. 

“The density fluctuations in the cosmic microwave background (CMB) provide the seeds for modern cosmic structure to form, including stars, galaxies, clusters of galaxies, filaments, and large-scale cosmic voids. But the CMB itself cannot be seen until the Universe forms neutral atoms out of its ions and electrons, which takes hundreds of thousands of years, and the stars won’t form for even longer: 50-to-100 million years.” (BigThink. The strongest evidence for a Universe before the Big Bang)

“Regions of space that are slightly denser than average will create larger gravitational potential wells to climb out of, meaning the light arising from those regions appears colder by the time it arrives at our eyes. Vice versa, underdense regions will look like hot spots, while regions with perfectly average density will have perfectly average temperatures.” (BigThink. The strongest evidence for a Universe before the Big Bang)

“The quantum fluctuations that occur during inflation do indeed get stretched across the Universe, and later, smaller-scale fluctuations get superimposed atop the older, larger-scale ones. These field fluctuations cause density imperfections in the early Universe, which then lead to the temperature fluctuations we measure in the cosmic microwave background, after all the interactions between dark matter, normal matter, and radiation occur prior to the formation of the first stable, neutral atoms.” (BigThink. The strongest evidence for a Universe before the Big Bang)

“The quantum fluctuations inherent to space, stretched across the Universe during cosmic inflation, gave rise to the density fluctuations imprinted in the cosmic microwave background, which in turn gave rise to the stars, galaxies, and other large-scale structures in the Universe today. This is the best picture we have of how the entire Universe behaves, where inflation precedes and sets up the Big Bang. Unfortunately, we can only access the information contained inside our cosmic horizon, which is all part of the same fraction of one region where inflation ended some 13.8 billion years ago.” (BigThink. The strongest evidence for a Universe before the Big Bang)

“If you look farther and farther away, you also look farther and farther into the past. If the number of galaxies, the densities and properties of those galaxies, and other cosmic properties like the temperature and expansion rate of the Universe didn’t appear to change, you’d have evidence of a Universe that was constant in time; that is not what we see.” (BigThink, Even before the Big Bang, space wasn’t truly empty)

Where there were no other electromagnetic fields. Electrons were just formed. The suggestion of how those fields formed, or which was the formation order of those fields, is that first were strong nuclear interaction fields, because those fields are radiation or wave movement that formed in the quark gluon plasma. Those high-energy particles condensed from the whirls in the gravity field. Then we must remember. Electromagnetic fields form in electron interactions. The weak nuclear interaction forms between protons and neutrons. That model mean. Electromagnetic fields formed before the weak nuclear interaction, because the weak nuclear interaction requires baryons that can form only if quarks can form protons and neutrons.  

So the four fundamental forces formed in the next order. 

1) Gravity

2) Strong nuclear interaction

3) Electromagnetism

4) Weak nuclear interaction. 

When we talk. About the force formation. We talk about. The situation, the environment, and the force that. Takes the form that makes their interaction possible. 

That means energy that existed before the Big Bang formed the universe. But where does that energy or wave movement come from? The logical explanation can be. The origin of that field or gravity waves could be another universe. The existence of other universes is logically possible. That model mean. That universes form structures like galaxies and galaxy clusters. But if we observe those kinds of theorems. We face one reality. If another universe exists and some particle travels between that universe and our universe, that hypothetical particle must travel through an extremely low-energy space. This means that there is no energy that can press the quantum field. 

That particle evaporates or turns into a wave movement. This would happen. Even if our universe were alone. This means that the dark energy’s origin can be in the space outside the universe. When a particle turns into a wave movement, it sends an energy impulse around it. Or it releases energy that condensed into that particle. This energy travels back to the universe. In the same way, a black hole that travels  out of the universe detonates. Every day, particles flow out from the universe, and that means there can be multiple energy sources outside the universe. If energy travels out from another universe, that low-energy spacetime will stretch that wave so long that it's hard or even impossible to detect. 

But then back to the Big Bang. The question is, where does the first universe get its existence? That is the question that makes the multiverse theory quite hard to control. Where did the first universe get the wave movement that formed it?

https://bigthink.com/starts-with-a-bang/evidence-universe-before-big-bang/

https://bigthink.com/starts-with-a-bang/universe-wasnt-empty-before-big-bang/

https://scitechdaily.com/universes-first-magnetic-fields-were-as-weak-as-human-brain-waves/