The Dark Shell (4) Neutron Balls

The Dark Shell (4) Neutron Balls

07/04/02

It may be that dark shells are paired and that one is composed of matter and the other is composed of anti-matter. If so, it might be presumed that dark mater constitutes a third type of basic matter. If a triple point singularity in one dark shell gives rise to a universe in the other shell, then a universe would be destroyed when it finally hits the inside of its containing shell. Certainly it would be an ending of epic proportions. Indeed, it would be grand fireworks on a cosmic scale.

07/11/02

Assuming that a spiral galaxy impacts obliquely on a smooth, flat portion of the inside of a dark shell and that the dark shell is composed of regular matter (i.e., not anti-matter), then there would be two points on the periphery of the spiral galaxy which should be ejected parallel to the surface of the dark shell. One point is located on the leading impacting edge of the galaxy and one would be on the trailing edge. Some wrinkling and folding of dark shells seems likely.

07/13/02

It may happen that a tear occurs in the skin of a dark shell and that it is not capable of self repair. In such case, it could then expand greatly until half of the surface of the dark shell remained. Thereafter it would shrink back to form a new ultimate black hole which is probably more appropriately termed a "ballooning black hole (BBH)." This process would be rather slow, say less than 1 percent of the speed of light. It could then happen that a universe could be created and that the forming BBH would never be seen by or contacted by the universe. It would seem probable that this cycle of reformation by a BBH could happen many times (e.g., hundreds of trillions of times) and could involve the assimilation of other dark shells. The edge of the opening would be relatively massive. Further it would seem that some remote regions of the dark shell might continue to cycle (i.e., oscillations of the wall of dark matter and baryonic matter) even if the size of the tear was substantial. Thus hundreds or thousands of cycles might occur in remote regions while the size of the tear increased.

The structure of baryonic matter within a dark shell is of interest. It would seem that, at some stage, it would be dominated by surface mathematics and star formation activities. It would be rather chaotic. There may be regions of folded or semi-folded dark matter present (independent of black holes).

A tear in the skin of a dark shell might be caused by an abnormal or rogue triple point singularity.

It would seem probable that the expansion of a new BBH would begin prior to the complete absorption of the fragments of the old configuration. Thus ragged wall-like pieces should festoon the surface of the new BBH as it expands. These fragments may fall over onto the expanding surface creating thicker regions which would expand more slowly than other areas. Further, these thick regions themselves may generate expanded inclusions within the dark shell. Thus, a universe which has been excluded in the reformation process may well, in part, impact on the exterior of a dark shell. Portions of the wall-like pieces also may project into the interior of the dark shell due to their inertia relative to the expanding dark shell. These may fall over onto the interior regions of the dark shell. [time for a beer]

07/17/02

Given the apparent abundance of dark matter and given its gas-like tendency to expand, some consideration should be given to the possibility of extracting energy from it. The first possibility would seem to be to attempt to deal with partially folded dark matter and to vary the amount of folding. Perhaps if a substance composed of only compact neutrons such as are found in neutron stars can be created, a neutron ball, then partial folding of dark matter in and near the neutron ball might occur. The space between two neutron balls would be of particular interest, particularly when they are spaced apart by a distance comparable to their diameters (assuming that they are the same size).

07/25/02

The skin of a dark shell is probably rather stable and should have a special structure. The surface may have a repetitive characteristics such as patterns of dimples or corrugated ridges. The structure should have a measure of complexity interior to the surface. All of these features may be difficult to determine given the large scale of the surface. Large patches or folded extensions of such surfaces should be found within the thickness of a dark shell given the chaotic history of such structures. Its composition would be folded, partially folded and compact dark matter. There should be a process for its creation and for its dissipation.

The formation of the skin probably precedes and causes the ballooning effect. Some critical mass of folded dark matter would be required and some special configuration of folded matter, some particular grouping, would be required. The result would be an unfolding of some of the folded dark matter deep within the critical mass. This process would probably not occur when or as a big bang was occurring as the transition is in effect very swift even though the accumulation process is long. If the skin is to be stable or at least reasonably stable, then one must postulate that there is a limit to the unfolding and that some minimum thickness is required for the unfolding. When this limit is reached in any direction, the unfolding stops and the skin then would have its minimum thickness.

08/05/02

To summarize, it appears that, in order of descending energy levels, there is dark matter which is (1) folded, (2) partially folded, (3) compact, and (4) expanded or expanding. Conservatively, one might assume that folded dark matter is to be found only when the conversion from the triple point singularity to the big bang occurs. An alternative argument would be that it also exists in large black holes. In any case, the interesting condition would seem to be partially folded dark matter which arguably is found in black holes of all sizes.

One way to visualize the situation might be to image that dark matter has a dual space time characteristic.

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