Initial mass in Pre Planckian space-timed defined , and causal discontinuity

This document reviews the Landau – Liftshifts reformulation of General relativity with a representation of the available mass of a graviton. From looking at a conservation law, using the Landau-Liftshifs formulation, we obtain conditions for initial mass, in the Pre Planckian regime of space-time. In doing so, we also indicate a metric tensor and metric pseudo tensor delineation of causal discontinuity. Key words, Massive gravitons, Landau-Liftshifts pseudo tensor, causal discontinuity.


Introduction
We will use the Poisson formulation of the Landau-Liftshifts formulation of General Relativity [1] in order to obtain an initial mass, in the Pre-Planckian Regime of space time.Using a modification of the Heisenberg Uncertainty principle, we also obtain an inter relationship between an inflation, initially, and initial mass.Finally, we reference the issue of a causal discontinuity, with surprising implications.
We first begin by a recapitulation of the different models for HFGW as given by Dr. Li et al., 2008 [2].This reproduced PRD table [3] is important since it suggests that relic GW, if properly measured, may be the first ones to await experimental verification.But in order to do this, we add in several caveats, as to after the fact considerations.
We are considering using massive gravitons [4] 1. Our methodology suggests that if we measure relic gravitational waves, that we will have to consider if an initial mass in the evolution of the universe, actually existed [1].
We also review, by example, if there is a way to use a modified version of the Heisenberg uncertainty principle, as given in [5].

2.
To obtain an inflation, in the onset of expansion of the Universe.
By way of our construction, we will also look at if a causal discontinuity exists as an elaboration of [3].
Having said that, it is time now to unveil by way of the Poisson reference [1] initial mass, and to tie it into our four issues brought up above.But before this, we will allude to our basic work horse, i.e. the Ng Entropy.
Entropy generation via Ng's infinite quantum statistics (short review) We wish to understand the linkage between dark matter and gravitons.To consider just that, we look at the "size" of the nucleation space, V. V for nucleation is HUGE.
Graviton space V for nucleation is tiny, well inside inflation/therefore, the log factor drops OUT of entropy S if V chosen properly for both Equation (1) and Equation (2).
Ng's [6] result begins with a modification of the entropy/partition function Ng used the following approximation of temperature and its variation with respect to a spatial parameter, starting with temperature R can be thought of as a representa- tion of the region of space where we take statistics of the particles in question).Furthermore, assume that the volume of space to be analyzed is of the form (where n is graviton density).Begin with a partition function This, according to Ng, [6] leads to entropy of the limiting value of, if [ ] ( ) But ≈ .The modification of Ng's entropy expression [6] is in the region of space time for which the general temperature dependent entropy Kolb and Turner expression breaks down.In particular, the evaluation of entropy we do via the modified Ng argument above is in regions of space time where g before re heat is an unknown, unmeasurable number of degrees of freedom The Kolb and Turner entropy expression [7] 1991 has a temperature T related entropy density which leads to that we are able to state total entropy as the entropy density time's space time volume   [ ] Essentially, what will be done is to use Equation ( 4) to show linkage between a largely thermally based production of entropy, as implied by Equation (3) and a particle counting algorithm, as given by Equation ( 2).This due to the problems inherent in making connections between a particle count generation of entropy, and thermal contributions.i.e. two different processes are involved.

The Poisson Rendition of the Landau-Liftshitz Effective Initial Mass
To do this go to [1] and the non Tensorial form of the Einstein field equations starting with the so called Gothic inverse metric, with a 2n line of Equation ( 5) being a tensor identity ( ) Furthermore, the two equations in Equation ( 5) have a representation of the GR field equations as If so then, we can have a simple solution to this above which is of the type ( ) Here, in this situation we have that if we are following the ideas in [5].
where we have restriction to the zeroth (time component) of the metric tensor, so that ( ) ( ) We will be looking at the value of Equation (7) if In short, we have then that by [5] ( ) ( ) If we use the following, from the Roberson-Walker metric [9] [10] [11]. ( Then, the surviving version of Equation ( 9) and Equation ( 10) is, then This Equation ( 11) is such that we can extract, up to a point the HUP principle for uncertainty in time and energy, with one very large caveat added, namely if we use the fluid approximation of space-time [5] ( ) Then by [10] [11] ( ) Then, ( ) Here, we have a causal discontinuity as given by ( )( ) We will address the implications of Equation ( 15) in the conclusion If we then put in the initial mass, of say from [1] of ( )( ) With the minimum scale factor a small, but non zero factor by [12]

Conclusion, Implication of Causal Discontinuity as Implied by Equation (17)
Note that having the right hand side of the 2 nd line of Equation ( 17) going to zero is implying that there is an invariance as to the gravitational field pseudo tensor, which may have implications as to the entropy-information transfer from Pre-Planckian to Planckian space-time, however we have to consider the Pre-Planckian to Planckian physics of the more traditional stress energy tensor.What we will say, is that by [5] and [13] if we have that the 2 nd line of Equation ( 17 Dispersal of the terms alpha and beta, into the non time components of the stress energy tensor would be saying also that 00 00 Pre-Planckian Planckian Note that in [13] we have that

Quote
These gapless Goldstone modes are the quantum carriers of information and entropy.
Analyzing their effective theory, we observe the information-processing properties strikingly similar to the ones predicted by the black hole portrait.The energy cost per qubit of information-storage vanishes in the large-N limit and the total information-storage capacity increases with N either exponentially or as a power law.

End of quote
Our idea is that the N limit, of information entropy, is akin to graviton counting, using the information given in Section 2, as given by Ng [6] and that if or not we have gravitons in a counting mode will be strongly affected by a possible causal discontinuity as given by Equation (19).If or not we have a causal continuity or discontinuity will also be affected by the simple minded rendition of inflation physics, whereas If N being a graviton count is sufficiently large, and the initial inflation can be para- As the number of Kaluza Klein gravitons per unit time per unit volume Note that this production rate is for a formula assuming mass for which * X T M > , and that we are assuming that the temperature T T * .Furthermore, we also are looking at a de facto total production rate of KK gravitons of the form [14] ( )  On the wave zone with an effective cross section of or less than 0.01 meters squared, for gravitational radiation where R is the assumed higher dimension "size" and, d is the number of dimensions above 4, and typically we obtain 1 T R  .
This with additional work may allow us to distinguish between the GW and gravity models as given in reference [16] by Corda as well as giving more definition to the issues brought up the the LIGO analysis of gravitational waves, as given in [17] and [18].
a linkage would open up the possibility that the density of primordial gravitational waves could be examined, and linked to modeling gravity as an effective theory.
) equals zero, with this reflecting the 00 Pre-Planckian T as a time line fluid momentum density (assuming c = 1 in units) and Planckian T αβ being a general stress energy tensor when we have Planckian, as opposed to Pre-Planckian conditions, that we say that [8] details of linking what is done with Equation (2) and bridging it to Equation (3) await additional theoretical development, and are probably conceptually understandable if the following is used to link the two regimes.i.e.we can use the number of space time operations used to create Equation (2), via Seth Lloyds[8] meterized, we can understand if or not Equation (19) is a causal structure discontinuity.