Tuesday, March 11, 2014
The Fourth Part of the Eighth Session of Course 16
When substringular phenomena work to rebound -- from a relatively forward-holomorphic directoral topological sway of a group of one or more respective given arbitrary superstrings, into a relatively reverse-holomorphic directoral topological sway of a group of one or more respective given arbitrary superstrings -- these superstrings are then undergoing an antiholomorphic Kaeler Condition that may then here be considered to directly afterward cause the activation of a Wick Action eigenstate, that is utilized to form the activity of a directly ensuing Gaussian Transformation. The activity of that group metrical-based activity of a Gaussian Metric that directly involves the motion of a group of one or more superstrings that are shook in a Klein Bottle eigenstate, over a series of 191 consecutive general metrics of such an eluded to activity of substringular shaking, in so as to allow for the said directly associated superstrings to re-attain that fractal of discrete energy that these need, in order for the just eluded to substringular phenomena to continue to exist as quanta of discrete energy. So, in a very real tense, the substringular activity of the rebounding of superstrings tends to indicate the relatively ensuing activity of a Kaeler Metric eigenstate. Calabi Metric eigenstates are specific cases of Kaeler Metric eigenstates, in which the directly corresponding superstrings that are Gliossi in a metrical manner to the needed reactivation of their discrete energy, happens in such a manner in which the directly corresponding photons are scattered in so as to form the needed quanta of discrete entropy, so that the needed entropic photons may exist, in order for their to be the ability of changes in physical state to occur. So, Calabi Metric eigenstates are more involved with the scattering of those ghost anomalies that are directly associated with those cohomologies that are appertaining to the interaction of electromagnetic energy with any given arbitrary set phenomena that any given arbitrary set quanta of discrete electromagnetic energy may be directly striking, in a Gliossi manner at the Poincaire level of the just eluded to substringular level. In any case, the "bouncing" and the rebounding of superstrings that occurs in any given arbitrary case is associated -- in one form or another -- to one form or another of a Kaeler Metric eigenstate. Such "bouncing" or rebounding of superstrings that directly involves such a format of an antiholomorphic Kaeler condition that involves discrete units of electromagnetic energy (photons) is a specific case of the Kaeler Metric that is known of as a Calabi Metric eigenstate. Calabi Metric eigenstates bear their chief importance, when in terms of that scattering of ghost-based anomalies that is needed in order to both replenish room for superstrings to have an arena of kinematic activity, as well as in order for there to be a tense of physical residue that is needed in order for those dilatons and dilatinos to be able to be formed so that both gravitons and gravitinos may be formed (so that gravity may have a kinematic-based substrate to be enacted so that gravity may continue to exist). Again, gravity is needed in order for physical phenomena to be able to bear some adjaent amplitude, so that superstrings may bear the general condition of bearing some significant effect upon each other. Such a revamping of the substringular environment, that is needed in order for superstrings to continue to kinematically codifferentiate -- is the general source of the prevention of black-holes. The motion of neutrinos is often a key to allowing for an efficient production of entropy that is not obtrusive, in so that the directly affiliated photons may form entropy that is condusive to a bearing less of a potential for the fraying of superstrings. I will continue with the ninth session later! Sincerely, Sam Roach.
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Labels:
Calabi,
Gaussian,
Gliossi,
Kaeler metric,
superstrings
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