A Little More About Gravitational Particles

Gravitons and gravitinos are respectively the angular momentum and the spin-orbital momentum components of gravitational force, when taken particle-wise.  Dilatons work to form gravitons, while dilatinos work to form gravitons.  As dilatons form, the angular momentum components of gravity are locally reformed in an indistinguishably different eigenstate in a conformally invariant-based specific general location.  As dilatinos are formed, the spin-orbital components of gravity are locally reformed in an indistinguishably different eigenstate in a conformally invariant-based specific general location.  As gravity spins various phenomena, as well as when gravity orbitally interacts with the same general phenomena, gravitinos are the specific type of particles are utilized to form such a general type of operation-based kinematic activity.  Gravity is necessary for matter to have a constituent relation with other material-based phenomena, yet, the excessive accumulation of gravitational fields in a secluded region works to cause that activity that eventually forms black-holes.  This is because gravitons in excess cause a lack of a Jacobian-based normalization to the Ultimon divergence of negative-norm-states in such a manner that the ghost anomalies that such negative-norm-states are to elliminate may not be able to be scattered with enough facilitation.  (Excessive quantums of gravity may often work to get in the way of the essential Gaussian Transformations that are needed in order for spaces and subspaces to interchage, interact, and kinematically undergoe successive Fourier Transformations.)  As the ghost anomaliic regions are not scattered, operands of normal substringular function are then, under the prior mentioned scenario, closed down.  Such unwanted kinematic operations depreciate the "choices" of potential world-sheet propagation, and thus initially cause a more limited Ultimon divergence of zero-norm-states.  This type of activity works to promote the build up of positive-norm-states in such a manner that a significant number of ghost anomalies that need to be scattered -- so that motion may be freed up -- are not being appropriately scattered.  As the said ghost anomalies are not elliminated, the path operands of normal stringular functions are decreased in number.  The key to help solve such a negative process is neutrinos.  These may be used to elliminate excessive ghost anomalic regions, since these fermions, which are mainly comprised of as one-dimensional strings, when tied in the right way to Planck phenomena bear norm-conditions that may be able to normalize the eigenbasis of the unorphoganated ghost anomalic regions.  The fermions, that have no charge directly associated with these, often bear a point mass that is smaller than that of an electron.  These, in a manner that I will not say, can settle upn the unnormalized mentioned region by having a common wobble tangency (1.104735878*10^(-81)Idegrees) that is bears fractal tension in enough of a degree to apply a tensorically-supplemental pulse upon the region that is to be changed.  The multiamorphous tendencis of massive neutrinos works to conform to the general region that is being considered in this case scenario, causing a successive change in norm-conditions that may thereby normalize the said general region as a catylist works upon a substrate.  Massive neutrinos of such a nature are thus like a fractal of "enzymes" that can work to orphogante unwanted anharmonic regions of ghost anomalies.  The two and three dimensional discrepencies of 2-d strings that are involved here are more anharmonic than those of 1-d superstrings, when dilaton-based energy is accumulated.  Superstrings tend to move anharmonically when the present entropy of stars is accumulated.  This mentioned entropy also tends to increase dilaton energy.  Dilaton "energy" is how I am here describing the force of gravity via the Ricci Scalar.  Sam.