ARGUMENT 0502-03

PRECEDENTS

0304-07: That when a blackhole absorbs a graviton, there is a decrease in its stability.

0304-08: That when a blackhole ejects a graviton, there is an increase in its stability.

0304-09: That when a blackhole is understable, it differentially ejects mass and energy until it becomes stable.

0304-10: That when a blackhole is overstable, it differentially absorbs mass and energy until it becomes stable.

0502-01: That every blackhole gravitonosphere consists of gravitonstreams in which the measure of dynamic mass varies from place to place.

0502-02: That many blackholes are within the gravitonospheric gravitonstreams of larger objects.

PARAMETERS

Consider a centrifugal blackhole that is within a gravitonstream.

Consider that the gravitonstream has a dynamic mass.

Consider that the blackhole has a dynamic mass.

Consider that the dynamic masses of the gravitonstream and the blackhole may be in equilibrium.

Consider that the dynamic masses of the gravitonstream and the blackhole may be out of equilibrium.

REASONING

Because the dynamic masses of the gravitonstream and the blackhole are out of equilibrium, the blackhole is either overstable or understable.

If the blackhole is overstable, it absorbs gravitons, and thus mass and energy, until it is stable.
If the blackhole is understable, it ejects gravitons, and thus mass and energy, until it is stable.

Because the blackhole is now stable, it's dynamic mass is in equilibrium with the dynamic mass of the gravitonstream.

Thus a centrifugal blackhole attunes itself to the dynamic mass of the gravitonstream it is within.

CONCLUSION

That a centrifugal blackhole will attune itself to the dynamic mass of the gravitonstream it is within.

To illustrate what happens on a larger scale, consider a log on the bank of a fast flowing river. While the log is stationary on the bank it is stable but tip it into the river and it immediately becomes overstable because it is not moving as fast as the river. However, it speeds up by absorbing energy from the water until it is moving at the same speed as the river - at which point it is stable again and in equilibrium with the river.

The argument perhaps gives the impression that attunement, once achieved, is a peaceful and constant condition. In real life, the dynamic mass of a gravitonstream is rarely constant for long. The nearer a gravitonstream is to an equator, the greater is its dynamic mass. Thus a blackhole's attunement is a continuing process. And, of course, blackholes can move from one gravitonstream to another.

A notable part of the attunement process is that a blackhole, given enough time, will adopt the least stressful orientation relative to the gravitonstream. The least stressful orientation has the blackhole's equator aligned to the gravitonstream's direction of flow. An example of this on a larger scale can be seen in the orientation of Planet Earth relative to the Sun - the gravitonosphere/atmosphere of both the Earth and the Sun is centrifugal and consequently the least stressful orientation is equatorial disc to equatorial disc.

Part 0502 - Axial Blackholes

ARGUMENT 0502-03