This is a work-in-progress and I could use some constructive input ...

Background: Particle physicists are at work back engineering the structure of matter. From their work they theorize the existence of certain particles and reactions, and as they push back the veil, they either confirm or deny the predictions.

Observation: Back engineering of particles and theoretical physics is likely to lead to the eventual discovery of a unifying force and an elemental particle from which everything else is constructed. I will refer to this future discovery as the Elemental Energy Wave/Particle (EEw/P or EEP for short).

Part of the reason that there is disagreement about the nature of black holes (or are they gravastars) is because we don’t yet fully understand particles and forces. My theory of how ultimate black holes solve the problem of increasing entropy in the greater universe predicts an elemental energy wave/particle (EEP).

Such a wave/particle will have to be simple and have characteristics that allow it to build the quantum particles and to carry out physics as we know it today. Here is a proposal for such a particle.

Proposed particle: The Elemental Energy Wave/Particle will have to be the tiniest particle and smallest unit of energy with infinitesimal mass. I can imagine it pulsing between a particle state and a wave state in such a way that at one instant this tiniest patch of energy can be expressed as a particle and at the next instant that particle transforms into wave movement of that particle in a pulsing sequence.

If one could follow that specific tiny patch of energy it would appear to be a particle at point A, then wave movement of that particle, and back to a particle at point B. Thus the EEP takes the form of a particle at point A and point B and it takes the form of wave movement between point A and point B as it moves with angular momentum.

The EEP can carry various amounts of energy and can transmit that energy to objects that it interacts with. The amount of energy is expressed by the length of the wave state. It seems backwards, but the amount of energy carried is inversely related to the length of the wave phase.

The change in wave phase (energy level) occurs only when particles interact. They can interact in several ways. Two particles can be “in phase” so that they express their particle state in the same place at the same time, i.e. “coincident expression”. When this occurs, those particles are “fused” (probably another bad choice of word) and the next wave phase expresses the energy and mass of both particles, energy value = 2 (EEP2), and the direction of movement is altered into forward movement that bisects the angle between the paths of the two former particles. In this interaction there is no net loss of energy, and there is no emission from the interaction. It is not a collision, but coincident expression of the particle state in the same space. The resulting wave/particle is an EEP2 with twice the energy and mass and a shorter wave phase.

The “coincident expression” is just one way these particles can interact. If they cross each others path in the wave state, the path of both particles is altered in an equal exchange of angular momentum caused by the interference.

If one EEP1 expresses its particle state in the path (in the wave state) of another EEP1, it gains or loses energy (shortens or lengthens its wave state) and it takes or gives energy to the other EEP. This type of interaction averages out so that on average the EEP with the lowest energy and longest wave state gains and the EEP with the most energy and shortest wave state gives energy in a particular environment. Both remain EEP1s but at different energy levels. Their value would be EEP1 + or – the exchanged (gained/lost) energy, i.e., EEP0.99 or EEP1.01 or something like that. This type of interaction insures that the average energy state in a particular EEP environment is maintained.

Fusing endures while the energy exchange due to passing interactions is very dynamic, i.e. it is “ever-changing” with each interaction always tending towards equalization if the energy of the EEPs in the environment and therefore towards stabilization of the EEP environment.

It would be impossible for an EEP to be reduced to EEP0.0 even after an unlikely sequence of losing interactions. If the energy of an EEP were to be able to go to zero, all of its energy having been transferred to other EEPs, it would not be able to express a particle state after that and so is impossible. The minimum amount of energy that an EEP can carry is a constant.

At absolute zero EEPs are “frozen” and condense in their wave state but have not become EEP0.0. When temperature returns they go on to express their particle state and continue to pulse again.

Particles can grow by fusing, i.e. coincident expression, but they are limited by their environment. Particles in the same environment are all interactive and the average of their energies is predominant throughout the environment. One EEP will not gain mass or energy disproportionately while the others in its environment give up their mass through “coincident expression” or give up their energy by “losing” interactions disproportionately. At least it is highly improbable.

One characteristic of an EEP2, EEP3, …EEPN (the 2, 3, …N is a way to characterize the average energy level of the environment that they are fused in or are interacting in), is that the fused particles are almost impossible to separate once they are fused.

One way to “un-fuse” them is to apply near infinite heat and pressure (compression like in the core of a black hole). By the time they find themselves in such an environment they will have participated in nucleosyntheisis and would have been incorporated in much larger and less stable atomic particles. The near infinite heat and pressure of a black hole would break any such atomic bonds and negate all quantum bonds leaving only EEPs in the core.

To negate a quantum bond is to apply highly excited EEPs to the quantum environment, “flooding” the bond which releases the EEPs that make up the quantum particle. Quantum particles come from the union of stabilized EEPs in low excitement environments and in nature are rarely exposed to highly excited EEPs. When that occurs though, there is a strong release of energy and the creation of high energy particles that escape the negation. The portion of the quantum particle that does not escape as a high energy particle is negated into EEPs.

At that point and in that environment EEPs would reach “maximum excitement” and begin to force their energy beyond their immediate environment, i.e. they annex the nearest lower energy level environment and if at maximum compression they repulse energy trying to enter their immediate environment; they begin to overcome the compression by eroding the matter that is containing them by this forcing and repulsing action at the boundary of the core where negation takes place.

They can also be un-fused by moving them to a lower energy environment that is not under unusual compression. They will give up their energy to surrounding lower energy EEPs through interaction and move down from EEPN to EEPN-x where N is the energy level before the interaction, and x is the reduction in energy given up to the other lower level EEP in the interaction. The lower energy level EEPs will gain by such a mixing and the environment will begin to stabilize. This is not a chemical reaction that takes place at the atomic level; these interactions are sub-atomic, sub-quantum particle interactions, only in environments made up of unstabilized EEPs. The un-fusing in this type of environment occurs when the average energy of the higher energy EEPs is reduced by one energy level. This process is primarily important during the early instants of a big bang and allows for unique levels of EEPs to form and reform before stabilizing, adding to the diversity of stabilized EEP environments and therefore to the ability to form diverse quantum particles.

The fusing and growing of EEPs is also environmentally dependant. Their E level (energy level as in EEP1, EEP2, …EEPN) stabilizes across the immediate environment at lower excitement levels. Higher excitement levels are not as conducive to stabilization.

As two different stabilized environments are mixed, instead of fusing and un-fusing, unique particles are formed as two different types of stabilized EEPN particles combine. It is the interaction of stabilized EEPNs that result in or “grow” various quantum particles. The type of quantum particle is determined by the environments in which the constituent EEPs were stabilized.

Quantum particles will bond in different ways and as they do they gain atomic particle status. This is the subject if investigation in quantum physics and Nucleosynthesis which goes on to describe how heavier elements are formed. Ultimately, these heavy elements will be drawn into a black hole.

The core of the black hole consists of high energy EEPs under extreme pressure and heat. The type of black hole determines that amount of compression. A collapsed star or a black hole at the center of a galaxy will generate a core of EEPs but the compression will not be sufficient to raise them to maximum excitement, or to lock them and repress their wave state.

If a black hole continues to grow via an accretive disk, the size of the EEP core grows under such extreme pressure that eventually the EEPs are “compression locked” in their particle phase and cannot move to express their wave phase. Gravity drives the in-flow from the accretive disk, and kinetic energy drives the gamma chaos that destroys atoms freeing their quantum particles. The boundary between the core and the event horizon is the “refinery” where EEPs are un-fused from quantum particles through negation and the EEPs join the core at maximum excitement.

The repressed wave phase of the locked EEPs is a growing time bomb. Through the erosion of the boundary between the core and the surface containing the core due to maximum excitement, as the surface area of the core grows, the erosion accelerates. When the rate of erosion overcomes the accretive growth of the UBH, the UBH has reached critical capacity and the eventual big bang becomes determinate; nothing can reverse the process.

We are not talking about a micro black hole, or a collapsed star, or even a black hole at the center of a galaxy; we are talking about an ultimate black hole (UBH) of proportions large enough to contain the “stuff” of our entire known universe.

The EEPs are the wave/particles that are released at the instant of a big bang.

They go from being extremely compressed (locked) at the last instant of the big crunch, to exponential expansion at the first instant of the big bang. Their environment abruptly changes, EEP interactions (slowly at first due to high excitement) begin to occur and EEPs begin to fuse through coincident expression of the particle state, and the expansion quickly sorts them into a variety of environments where various forms of EEPs are stabilized. These stabilized environments begin to mix and different types of stabilized EEPs begin to combine into quantum particles. Particle clouds form, stars are born, and Nucleosynthesis beings the process all over again.

Conclusion: There is an as yet undiscovered Elemental Energy Wave/Particle (EEP) that solves problems of particle physics, explains the sub-quantum environment, offers an explanation of gravity, defeats increasing entropy in the grander universe, explains the nature of the early moments of the big bang, allows for ultimate black holes (big crunches), and orchestrates the formation and destruction of quantum and atomic particles.

Here are some EEP characteristics:

Pulsing between a wave state and a particle state.
Distance of wave phase movement depends inversely on the energy level of the wave/particle.
Ability to “fuse” through “coincident expression” of the particle state.
Number of fused EEP particles making up an EEPN is variable and limited by their environment which tends to average out their mass and energy across the immediate environment, i.e., after a big bang, inside a “dust” cloud (pre-quantum particles) or at the birth of a star.
Each EEP has angular momentum.
Each EEP has an Energy level that can vary between a low limit and a high limit.
EEPs at absolute zero cannot express their particle state, i.e. are frozen in their wave state and condense or fall together (but I don’t think this ever happens in the natural universe due to the average density and temperature of the universe that defies absolute zero).
Beyond the low limit the EEP theoretically would fail to express its next particle state, and disappear by interaction, but it is impossible for it cannot give up its last level of energy by interaction.
At interaction the EEP with the longer wave phase (less energy) gains at interaction with another EEP with a shorter wave phase (more energy) and the EEP with the shorter wave phase (more energy) loses.
Continuity: many interactions are taking place in close proximity at all times resulting in a continuum that keeps all EEPs connected across any distance and interactions are translated over short distances instantly and over long distances rapidly.
Diminishment limit; smallest energy possible in an EEP; this could be a constant.
Excitement limit; There is a limit, the most energy that an EEP can carry (also a constant), beyond which its wave phase becomes infinitely short. These particles are forced to give energy to lower energy EEPs until all EEPs in the immediate environment are at the maximum excitement level, i.e. in the core of a black hole.
Negation is the destruction of quantum particles caused by flooding the quantum particle with highly excited EEPs. Negation results in various cosmic rays and the ultimate release of EEPs from former quantum particles.
Compression locked EEPs have maximum potential energy.
Gravity is the change in angular momentum (curving) as EEPs interact.
EEPs fuse and grow through interaction into quantum particles, and quantum particles grow to atomic particles; Nucleosynthesis.
If all of the EEPs were at identical energy levels and if they were separate and in their own space, i.e., fully disbursed throughout the universe in a fully disbursed state (no interaction with other EEPs) they would be in a state of equilibrium (impossible in nature but philosophically this state would represent the average density of the universe at an average temperature above absolute zero and at a density of one EEP1 per cubic bogie-meter).