The Dark Shell (3) Baryonic Matter

The Dark Shell (3) Baryonic Matter

05/01/02

Since most of the matter in the universe is dark matter, it can be postulated that just prior to the big bang, most of the source was folded dark matter. Probably the best way to think of the transition between the singularity and the start of the big bang is to consider the transition to be a type of spatial/time mapping process.

What is the shape of the singularity? If one supposes that the radial (inward) wave is only a trigger, then the two colliding equatorial waves form the essence of the singularity. Intuitively therefore one might argue for an oval shape with the major axis aligned along the equator. Is the singularity flat or curved and what are the directions of entry? Assuming the outline is oval, perhaps an ovoid (football) shape is a good first guess with entry from any direction.

05/06/02

As our universe is rapidly expanding, one can assume that the expansion will continue for a long time. However, it would seem that there should be a final limit to the amount of the expansion of dark matter. Assuming that the wall of dark matter is stable, then one could assume that at the surface, the dark matter begins to be less dense and that it expands outward away from the wall to its natural limit. It would be like a sea of tall grass.

The density of the wall itself is probably rather irregular as the distribution of baryonic matter within it would be uneven. Further there well may be traverse waves along and/or well into the surface, much like waves on an ocean.

05/16/02

It would seem that the average direction of travel of baryonic matter within the wall would be roughly parallel to the surface. This assumes that the motion of the baryonic matter in the wall has reached something of a steady state condition. However, a substantial amount of motion of baryonic matter into or away from planes parallel to the surface seems likely.

One can postulate that hundreds of universes are created during each inward part of a cycle and if so, then one could also postulate that hundreds of universes impinge upon the surface mainly during the outward part of the cycle.

The closure rate of a universe on the surface may be high and many collisions can be anticipated. One aspect which would affect the amount of chaos involved would be whether both matter and anti-matter universes impinge on the surface. The absolute size of each universe may vary substantially. It probably would be a function of what part of the inward cycle was involved when the singularity was generated. If the composition of the surface is not homogeneous, then the amount of dark matter relative to baryonic matter in a given universe may vary substantially.

05/18/02

Perhaps only a few hundred or thousand universes exist at any moment. Assuming that 100 are created and assimilated each cycle, the estimate of 200 billion cycles would mean that 20 trillion universes have been created with only the most recently formed ones still in existence. As the mass and energy (Q) of the wall would drastically exceed that of an average universe, the impact and assimilation of a universe into the wall would be a rather minor event, unless of course you are along for the ride. The fundamental character of the wall is probably very stable in spite of the chaotic internal conditions. Is the singularity which the focal point of collection of dark matter and baryonic matter contiguous with the point at which the big bang occurs? One could argue for a displacement. There seems to be no reason for example why a big bang could not occur within the wall itself. Does the existence of the singularity, once formed, depend upon being imbedded within the wall? Probably not as it would have its own boundary conditions and restraints. What is the topology of the wall if it is a closed system? Does the amplitude of the oscillation of the wall vary in different parts of the wall? If bounded, which seems probable, does the overall system resonant (i.e., having different modes or frequencies of oscillation in different parts of the wall)? Are there transitory voids within the wall?

05/23/02

The oscillation of the surface should have a sorting effect on the baryonic matter within the wall. A type of inertial sorting may result. This effect would be superimposed as a tidal action on the more or less random motion of the contents. Also shock waves which compress baryonic matter over extensive areas should be common. If most or all of the dark matter in the wall is compressed (at a density comparable to that found within a constraint radius around a baryonic mass), then it must be presumed that it is rather inert and stable -- at least as compared with our universe where it seems to be expanding rapidly.

06/02/02

The outer bound of the wall may be composed of a layer of folded dark matter -- a kind of extremely compact region which could be called a "skin" of sorts. This would require special boundary conditions on both sides of the layer.

06/04/02

So how is this primordial oscillating structure formed? Let’s start with a soup of diffuse dark matter and baryonic matter. A lot of matter. Enough to form trillions of universes. Now let us postulate a perturbation that causes aggregation to commence. Gradually a black hole is formed, then a super massive black hole and finally an ultimate black hole. Virtually everything is in the ultimate black hole. Although very compact, it is also very large. Most of it is folded dark matter. It is so large that, even though it is extremely compact, it is many billions of light years across.

A slight perturbation lessens the density of the object away from the exact center. Ultimately there is a shift of mass away from this region of lower density toward the surface together with the shrinking of the ultimate black hole to a very large but still much smaller black hole. The lower density region expands since dark matter tends to expand. The dense outer skin is still largely comprised of folded dark matter and it expands greatly but remains intact. The center of the structure becomes a void. The presence of the large black hole at the surface sets up the basic oscillation of the structure. The very large black hole becomes part of the surface and/or skin. The oscillations continue for a very long time and occasionally create a triple singularity from which a universe can be formed.

06/06/02

Perhaps the name "dark shell" could be used to describe the overall structure. The dark shell would oscillate with the least movement occurring near the remnant of the ultimate black hole.

06/07/02

The transition from the ultimate black hole configuration to the dark shell configuration might best be called the great expansion. Also, it can be surmised that there may be many dark shells.

06/09/02

Given the large size of a dark shell, its shape may be complex. Warping or folding of the surface seems likely. The most active regions of oscillation may be difficult to determine. Entrapped voids may be common but probably are transitory in nature. It could happen that two dark shells might collide. If the skin of one is torn, it should be able to repair itself if the tear is small. If the collision is not a severe one, there may be adhesion between them. Indeed, large clusters of dark shells which have adhered to each other's surfaces may occur. The relative sizes of the dark shells may vary considerably.

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