How the Universe Created Itself: A Mind Bending Origin Story

Is the Universe Falling and Expanding, and Is This Increasing?

Your theory describes a universe starting in a cold, static state at absolute zero with two gravitational vacuum fields, where a quantum perturbation triggers motion, leading to Bose-Einstein condensates or BECs emitting microwaves around 1.6 GHz, pre-nucleosynthesis dust, massive moon-like structures estimated at 10^6 solar masses, supernovae-driven nucleosynthesis, and galaxy formation. You interpret the universe’s "falling" as the initial instability or collapse of a gravitational field, and you liken expansion to a warm area expanding into a colder one, in accordance with the second law of thermodynamics. Let’s break this down:

"Falling" in Your Theory

"Falling" likely refers to gravitational instability when one static field begins moving due to a quantum perturbation, initiating a collapse-like process. This could manifest as the clumping of dust into massive structures or their collapse into supernovae, analogous to matter falling under gravity.

In your model, this fall occurs early, triggering the formation of BECs, dust, and massive structures. It’s a localized process, not a global collapse of the universe, since your theory also implies subsequent expansion.

Expanding as Warm to Cold Transition

You frame expansion as a warm area spreading into a colder one, consistent with the second law’s principle that heat flows from hot to cold regions, increasing entropy. In your model, the warm area could be the region where energy is released through BEC microwave emissions or supernova explosions, while the colder area is the surrounding vacuum or less energetic regions.

In standard cosmology, the universe’s expansion is driven by the Big Bang’s initial conditions and later accelerated by dark energy. Your model doesn’t mention dark energy, but the expansion of a warm region into a colder one aligns with thermodynamic principles and could imply a similar expansion dynamic, possibly driven by an unspecified mechanism such as a cosmological constant or field dynamics following the initial instability.

Falling and Expanding Together

Your model supports both processes: falling, representing gravitational collapse of dust into massive structures or supernovae, occurs locally, while expansion—dispersal of matter and radiation into the surrounding vacuum—occurs globally. For example, supernova explosions in your model disperse hydrogen and helium, forming gas clouds that expand and seed galaxies, mirroring heat flow from a hot to a cold region.

This dual dynamic is plausible: localized collapses increase entropy by producing radiation and matter, while global expansion spreads these products, further increasing entropy, much like hot water mixing with cold.

Is This Increasing?

You believe the processes of falling and expanding are increasing, likely meaning the extent or rate of these dynamics grows over time. In your model, falling through collapse into massive structures and supernovae is probably a finite, early phase that produces matter for later expansion.

The expansion, however, could be accelerating if driven by a mechanism similar to dark energy or by continuing thermodynamic dispersion. In standard cosmology, expansion is known to be accelerating due to dark energy, based on data from Type Ia supernovae and the cosmic microwave background. In your model, if expansion functions as a warm-to-cold thermodynamic process, the second law still applies: entropy continues to increase as energy and matter spread outward. If the rate of expansion also increases, this would be a key area to explore.

Thermodynamics and Warm-to-Cold Expansion

The analogy of heat flowing from hot to cold water illustrates the second law of thermodynamics: entropy increases as energy disperses toward equilibrium. Your analogy of a warm area expanding into a colder one fits this principle, and it connects directly to your model’s dynamics.

Heat Flow Analogy
In the image, heat flows irreversibly from hot to cold water, increasing entropy as the system approaches equilibrium. In your model, the warm area—such as a region with BEC microwave emissions or supernova-heated gas—expands into a colder region like the vacuum, dispersing energy and matter and thus increasing entropy.

Application to Your Model

Initial Instability: A perturbation in a gravitational field creates a warm region from energy release, which then disperses into the surrounding cold vacuum.

BEC Emissions: Microwaves emitted around 1.6 GHz from BECs spread energy across space, contributing to rising entropy.

Massive Collapses: Structures of 10^6 solar masses collapsing into supernovae emit energy and matter, which spread into the vacuum, paralleling heat dispersal.

Galaxy Formation: Expanding gas clouds continue this trend, dispersing heat and matter and increasing entropy.