We are in this document asking if Octonionic gravity [1] is relevant near the Planck scale. Furthermore, we ask if gravitational waves would be generated during the initial phase, of the universe when an increase in degrees of freedom that have in setting is used. We demonstrate how a Gaussian mapping, combined with a strange attractor will enable quantum gravity to form. The key development would be in using a strange attractor [2]. In addition, the supposition R. Penrose made: is presented with a more traditional cosmological constant, not varying over time? Does the Penrose model directly allow us to form a much simpler Entropy expression? However, in doing so, we make note of how a quartic phase transition initially may impose a level of precision in parameters impossible to verify with present experimental equipment.
This paper examines geometric changes that occurred in the very earliest phase of the universe, leading to values for δ 0 , and explores how we might gain insight through gravitational wave research. The Planck epoch has gravity wave background radiation containing the imprint of the very earliest events.
That the degrees of freedom increase, with an increase in temperature, is what we expect to happen during a transition to a Rindler Geometry flat space regime of space time.
Further elaboration of properties of a mutually unbiased basis (MUB), [
a ( t ) = cosh ( Λ / 3 ⋅ t ) Λ / 3 (1)
to a flat space FRW equation of the form [
( a ˙ a ) 2 + 1 a 2 = Λ 3 (2)
which is so one forms a 1-dimensional Schrodinger equation [
( ∂ 2 ∂ a 2 − 9 π 2 4 G 2 ⋅ [ a 2 − Λ 3 ⋅ a 4 ] ) Ψ = 0 (3)
with a ˜ 0 a turning point to potential [
U ( a ) = 9 π 2 4 G 2 ⋅ [ a 2 − Λ 3 ⋅ a 4 ] . (4)
What we are doing afterwards is refinement as to this initial statement of the problem in terms of giving further definition of the term ρ vacuum = [ Λ 8 π G ] . We
will model inputs into the initial value of Λ as high energy fluctuations, and see if they contribute to examination of non commutative geometry before the
inflationary era. This ρ vacuum = [ Λ 8 π G ] may enable tying vacuum expectation value (VeV) behavior with (
As by L. Crowell [
“The standard inflationary cosmology involves a scalar field φ which obeys a standard wave equation. The potential is this function which I diagram “above”. The scalar field starts at the left and rolls down the slope until it reaches a value of φ where the potential is V(φ) ~φ^2. The enormous VeV at the start is about 14 orders of magnitude smaller than the Planck energy density ~(1/L_p)^4 on the long slope. The field then enters the quadratic region, where a lot of that large VeV energy is thermalized, with a tiny bit left that is the VeV and CC of the observable universe. The universe during this roll down the long small slope has a large cosmological constant, actually variable λ = λ(φ, ∂φ), which forces the exponential expansion. There are about 60-efolds of the universe through that period. Then at the low energy VeV the much smaller CC gives the universe with the configuration we see today.”
One of the ways to relate an energy density to cosmological parameters and a vacuum energy density using a relation as given by (5), as given by Poplawski [
ρ Λ = H λ Q C D (5)
where if λ Q C D is at least 200 MeV and is similar to the QCD scale parameter of the SU(3) gauge coupling constant, and H a Hubble parameter. Here we consider
that if there is a relationship between Equation (5) above and ρ vacuum = [ Λ 8 π G ] then the formation of inputs into our vacuum expectation values V ≈ 3 〈 H 〉 4 16 π 2 , and also equating V ≈ 3 〈 H 〉 4 16 π 2 with V(φ) ~ φ2 would be consistent with an inflaton treatment of initial inflation. We have
ρ vacuum = [ Λ 8 π G ] ≈ ρ Λ ≈ H λ Q C D ⇔ V ≈ 3 〈 H 〉 4 16 π 2 ≈ V inf ∝ ϕ 2 (6)
Different models for the Hubble parameter, H exist, and can be directly linked to how one forms the inflaton. The authors presently explore what happens to the relations as given in Equation (6) before, during, and after inflation.
We first consider the construction given in [
| Λ 5-dim | ≈ c 1 / T α (7)
in contrast with the more traditional four-dimensional version, minus the minus sign of the brane world theory as given by Park [
Λ 4-dim ≈ c 2 T β (8)
| Time 0 ≤ t ≪ t P | Time 0 ≤ t < t P | Time t ≥ t P |
|---|---|---|
| | Λ 5 | undefined, T ≈ ε + → T ≈ 10 32 K Λ 4-dim ≈ almost ∞ | | Λ 5 | ≈ ε + , Λ 4-dim ≈ extremelylarge 10 32 K > T > 10 12 K | | Λ 5 | ≈ Λ 4-dim , T much smaller than T ≈ 10 12 K |
The difference between what Barvinsky [
Λ 4-dim ∝ c 2 ⋅ T β → gravitonproductionastime > t ( Planck ) 360 ⋅ m P 2 ≪ c 2 ⋅ [ T ≈ 10 32 K ] β (9)
Right after the gravitons are released, one still sees a drop-off of temperature contributions to the cosmological constant. Then [
Λ 4-dim | Λ 5-dim | − 1 ≈ 1 n (10)
If we examine | Λ 5-dim | ~ c 2 T − β
We assume a discontinuity in pre Planckian regime, for scale factors [
[ a ( t ∗ + δ t ) a ( t ∗ ) ] − 1 < ( value ) ≈ ε + ≪ 1 (11)
Starting with [
E thermal ≈ k B ⋅ T temperature 2 ∝ Ω 0 T ⌣ ≈ β ˜ (12)
The assumption is that there is an initial entropy, as temperature T ∈ [ 0 + , 10 19 GeV ] arrives. Then by [
Δ S = [ ℏ T t e m p ] ⋅ [ 2 k 2 + 1 η 2 ⋅ m Planck 2 ⋅ [ 12 4 π ϕ 2 ] ] 1 / 2 ≈ n particlecount (13)
The way to introduce the expansion of the degrees of freedom from nearly zero to having N(T) ~ 103 is to define the classical and quantum regimes of gravity as to minimize the point of the bifurcation diagram affected by quantum processes [
x i + 1 = exp ( − α ˜ ⋅ x i 2 ) + β ˜ (14)
Change of temperature, as given, is [
Δ β ˜ d i s t ≅ ( 5 k B Δ T t e m p / 2 ) ⋅ N ¯ d i s t ≈ q E NetElectricField ≈ changeindegreesoffreedom (15)
We would regard this as being the regime in which we see a thermal increase in temperature, up to the Planckian physics regime. If so, then we can look at what is the feeding in mechanism from the end of a universe, or universes, and inputs into Equation (14) and Equation (15).
Beckwith strongly suspects that there are no fewer than N universes undergoing Penrose “infinite expansion” [
{ Ξ i } i ≡ N i ≡ 1 | before ≈ { Ξ i } i ≡ N i ≡ 1 | after (15)
However, that there is nonuniqueness of information put into each partition function { Ξ i } i ≡ N i ≡ 1 . Furthermore Hawking radiation from the black holes is collated via a strange attractor collection in the mega universe structure to form a new big bang for each of the N universes as represented by { Ξ i } i ≡ N i ≡ 1 . Verification of this mega structure compression and expansion of information uses Ergodic mixing treatments of initial values for each of N universes expanding from a singularity beginning. The n f value will be used to algorithm of [
{ Ξ i } i ≡ 1 i ≡ N ∝ { ∫ 0 ∞ d E i ⋅ n ( E i ) ⋅ e − E i } i ≡ 1 i ≡ N (16)
Each of the terms E i would be identified with Equation (16) above [
1 N ⋅ ∑ j = 1 N Ξ j | j beforenucleationregime → vacuumnucleationtranfer Ξ i | i fixedafternucleationregime (17)
For N number of universes, with each Ξ j | j beforenucleationregime for j = 1 to N being the partition function of each universe just before the blend into the RHS of Equation (12) above for our present universe. Also, in the end [
Ξ j | j beforenucleationregime ≈ ∑ k = 1 M a x Ξ ˜ k | blackholes j thuniverse . (18)
In particular, in the regime where there is a buildup of temperature, [
∳ [ x j , p i ] d x k ≈ − ∳ p i [ x j , d x k ] = − β ˜ ⋅ l Planck ⋅ T j , k , l ∮ p k d x l ≠ − ℏ β ˜ ⋅ l Planck ⋅ T i , j , k (19)
Very likely, across a causal boundary, between ± l P across the boundary due to the causal barrier, one gets [
∮ p i d x k ≠ ℏ δ i , k (20)
I.e.
∳ ± l Pkack p i d x k → i → k 0 (21)
If so, [
[ x j , p i ] ≠ − ℏ β ˜ ⋅ ( l Planck / l ) ⋅ T i , j , k x k (22)
Furthermore we state that Equation (22) will not approach i ℏ δ j , i in the Pre Planckian regime.
Equation (22) means that in the pre Planckian regime, and in between ± l P , QM no longer applies.
To do this we look at the G. Ecker article [
[ x i , p j ] → temperature → ∞ i ℏ δ i , j (23)
In order to get conditions for Equation (24) the following can be referred to about non commutative geometry [
[ x i , x j ] = i ⋅ Θ i , j → temperature → ∞ 0 (24)
The essentials step is to say the anti symmetric real tensor is proportional to the square of 1 over the Parks representation of the “Planck constant”, which has a temperature dependence built in it.
Θ i , j ≈ [ Λ 4-dim ] − 2 ∝ 1 / T 2 β → temperature → ∞ 0 (25)
When Equation (26) goes to zero, leading to Equation (24) going to zero, we submit that then Equation (24) is recovering quantum/Octoinian gravity. The Equation (24) above, according to the G. Ecker article [
Passing gravitons through to a new universe is not the same thing though as a pre Planckian geometry, for Octonian gravity conditions arise in early Planckian space time.
The basics background we are referencing before proceeding is given in [
h min ≈ 1 Q ⋅ ℏ ω e − ξ (26)
This can be a significant limitation in practice. For example, as quoted from a document being written up by F. Li et al., for publication [
In this case hmin ~ 8.1 × 10−23 for the non-stochastic HFGW, even at a very low contained energy of 10 J. It is therefore quite plausible that such a detection cavity could be tuned over a range of HFGW frequencies to scan for detectible gravitational waves of either a coherent or stochastic nature. Given these figures, it is now time to consider what happens if one is looking for traces of gravitons which may have a small rest mass in four dimensions. What Li et al. have shown in 2003 [
i.e. what was called T u v ( 1 ) in terms of a non zero four dimensional graviton rest
mass, in a detector, in the presence of uniform magnetic field, when examining the following situation, i.e. [
T u v = 1 μ 0 ⋅ [ − F α μ F v α + g μ v 4 ⋅ F α β F α β ] (27)
Li et al. [
T u v = T u v ( 0 ) + T u v ( 1 ) + T u v ( 2 ) (28)
The 1st term in right hand side of Equation (28) is the energy-momentum tensor of the back ground electromagnetic field, and the 2nd term to the right hand side of Equation (28) is the first order perturbation of an electromagnetic field due to the presence of gravitational waves. The above Equation (27) and Equation (28) will eventually lead to a curved space version of the Maxwell equations as
1 − g ⋅ ∂ ∂ x ν ( − g ⋅ g μ α g ν β F α β ) = μ 0 J μ (29)
as well as
Eventually, with GW affecting the above two equations, we have a way to isolate T u v ( 1 ) . If one looks at if a four dimensional graviton with a very small rest mass included [
1 − g ⋅ ∂ ∂ x ν ( − g ⋅ g μ α g ν β F α β ) = μ 0 J μ + J effective (31)
where for ε + ≠ 0 but very small
F [ u v , α ] ≈ ε + (32)
The claim which A. Beckwith made [
J effective = n gravitoncount ⋅ [ m graviton ( 4-dimversion ) ] (33)
As stated by Beckwith, in [
appropriate T u v ( 1 ) assuming a non zero graviton rest mass, and using Equation (32), Equation (33) and Equation (34) below. From there, the energy density order contributions of T u v ( 1 ) , i.e. T 00 ( 1 ) can be isolated, and reviewed in order to obtain traces of β ˜ , which can be used to interpret Equation (14). I.e. use β ˜ ≅ | F | and make a linkage of sorts with T 00 ( 1 ) . The term T 00 ( 1 ) isolated out from T u v ( 1 ) present day data.
h 0 2 Ω G W ~ 10 − 6 (34)
Next, after we tabulate results with this measurement standard, we will commence to note the difference and the variances from using h 0 2 Ω G W ~ 10 − 6 as a unified measurement which will be in the different models discussed right afterwards.
We will next give several of our basic considerations as to early universe geometry which we think are appropriate as to Maggiore’s [
What we are expecting, as given to us by L. Crowell, [
n f ~ h 0 2 Ω G W ⋅ 10 37 3.6 ⋅ [ 1000 Hz f ] 4 (35)
Secondly we have that a detector strain for device physics is given by [
h C ≤ ( 2.82 × 10 − 21 ) ⋅ ( 1 Hz f ) (36)
These values of strain, the numerical count, and also of n f give a bit count and entropy which will lead to possible limits as to how much information is
| h C ≤ 2.82 × 10 − 33 | f G W ~ 10 12 Hertz | λ G W ~ 10 − 4 meters |
|---|---|---|
| h C ≤ 2.82 × 10 − 31 | f G W ~ 10 10 Hertz | λ G W ~ 10 − 2 meters |
| h C ≤ 2.82 × 10 − 29 | f G W ~ 10 8 Hertz | λ G W ~ 10 0 meters |
| h C ≤ 2.82 × 10 − 27 | f G W ~ 10 6 Hertz | λ G W ~ 10 2 meters |
| h C ≤ 2.82 × 10 − 25 | f G W ~ 10 4 Hertz | λ G W ~ 10 1 kilometer |
| h C ≤ 2.82 × 10 − 23 | f G W ~ 10 2 Hertz | λ G W ~ 10 3 kilometer |
transferred. Note that per unit space, if we have an entropy count of, after the start of inflation with having the following, namely at the beginning of relic inflation λ G W ~ 10 − 1 meters ⇒ n f ∝ 10 6 graviton / unitphasespace for f G W ~ 10 9 Hertz This is to have, say a starting point in pre inflationary physics of f G W ~ 10 22 Hertz when λ G W ~ 10 − 14 meters , i.e. a change of ~1013 orders of magnitude in about 10−25 seconds, or less.
To summarize, what we expect is that appropriate strain sensitivity values plus predictions as to frequencies may confirm or falsify each of these four inflationary candidates, and perhaps lead to completely new model insights. We hope that we can turn GW research into an actual experimental science. Note that in the following
The best targets of opportunity, for viewing Ω G W ≈ 10 6 are in the 1 Hz < f < 10 GHz range, with another possible target of opportunity in the f ∝ 10 − 6 Hz range. Other than that, it may be next to impossible to obtain relic GW signatures. Now that we have said it, it is time to consider the next issue. See Appendix D for a description of these cosmology models.
We can look now at the following approximate model for the discontinuity put in, due to the heating up implied in
Λ M a x V 4 8 π G ≈ T 00 V 4 = ρ ⋅ V 4 = E total (37)
The approximation we are making, in this treatment initially is that E total ∝ V ( ϕ ) where we are looking at a potential energy term [
V ( ϕ ) = g ⋅ ϕ α (38)
De facto, what we come up with pre, and post Planckian space time regimes, when looking at consistency of the emergent structure is the following. Namely, go to the following
| Relic pre big bang | QIM | Cosmic String model | Ekpyrotic |
|---|---|---|---|
| Ω G W ~ 6.9 × 10 − 6 when f ≥ 10 − 1 Hz Ω G W ≪ 10 − 6 when f < 10 − 1 Hz | Ω G W ~ 4 × 10 − 6 1 GH < f < 10 GH | Ω G W ~ 4 × 10 − 6 f ∝ 10 − 6 Hz Ω G W ~ 0 otherwise | Ω G W ~ 10 − 15 10 7 Hz < f < 10 8 Hz Ω G W ~ 0 otherwise |
V ( ϕ ) = g ⋅ ϕ | α | for t < t PLanck (39)
Also, we would have
V ( ϕ ) = g / ϕ | α | for t ≫ t PLanck (40)
The switch between Equation (39) and Equation (40) is not justified analytically. I.e. it breaks down. Beckwith et al. (2011) designated this as the boundary
of a causal discontinuity. Now according to Weinberg [
a ( t ) ∝ t 1 / ∈ (41)
Then, if [
| V ( ϕ ) | ≪ ( 4 π G ) − 2 (42)
There are no quantum gravity effects. I.e., if one uses an exponential potential a scalar field could take the value of, when there is a drop in a field from ϕ 1 to ϕ 2 for flat space geometry and times t 1 to t 2 [
ϕ ( t ) = 1 λ ln [ 8 π G g ∈ 2 t 2 3 ] (43)
Then the scale factors, from Planckian time scale as [
a ( t 2 ) a ( t 1 ) = ( t 2 t 1 ) 1 / ∉ = exp [ ( ϕ 2 − ϕ 1 ) λ 2 ∈ ] (44)
The more a ( t 2 ) a ( t 1 ) ≫ 1 , then the less likely there is a tie in with quantum gravity.
Note those that the way this potential is defined is for a flat, Roberson-Walker geometry, and that if and when t 1 < t Planck then what is done in Equation (44) no longer applies, and that one is no longer having any connection with even an octonionic Gravity regime.
Start with working with the expression given beforehand as [
E thermal ≈ k B ⋅ T temperature 2 ∝ β ˜ (45)
This is for having for a time T ⌣ ~ 0 + to 10−44 seconds, Ω G W ~ 10 6 , and a variance of frequency of
Ω 0 ∈ [ 1 GHz , 10 GHz ] (46)
This is due to T temperature ~ 10 32 Kelvin at the point of generation of the discontinuity leading to a discontinuity for a signal generation as given by δ 0 at about T ⌣ ~ 10 − 44 seconds. This is for inputs into the relatively constant
[ Ω 0 T ⌣ ] ~ β ˜ (47)
The assumption is that the discontinuity, as given by δ 0 will be as of about temperature T temperature ~ 10 32 Kelvin, for Ω G W ~ 10 6 , meaning that the peak curve of frequency will be between 1 to 10 GHz for Ω G W ~ 10 6 , with a rapidly falling value of Ω G W for frequencies < 1 GHz.
It is difficult. It depends upon understanding what is meant by emergent structure, as a way to generalize what is known in mathematics as the concept of “self-organized criticality” put forward by the Santa Fe school [
self organized criticality structure leading to forming an appropriate T u v ( 1 ) if one has non zero graviton rest mass? Answering such questions will permit us to understand how to link finding T u v ( 1 ) in a GW detector, its full analytical linkage to β ˜ in Equation (13), and Equation (14) [
a GW detector. This construction below is to be used to investigate “massive gravitons”/and also the initial structure of self organized criticality, in the aftermath of graviton/gravitational wave generation. Further details can be accessed in Appendix F as to a GW detection system which may be able to help us isolate
T u v ( 1 ) .
We are attempting to add more information than
We wish to summarize what we have presented in an orderly fashion. Doing so is a way of stating that Analog, reality is the driving force behind the evolution of inflationary physics
1) Pre Octonian gravity physics (analog regime of reality) features a breakdown of the Octonian gravity commutation relationships when one has curved space time. This corresponds, as brought up in the Jacobi iterated mapping for the evolution of degrees of freedom to a buildup of temperature for an increase in degrees of freedom from 2 to over 1000 per unit volume of space time. The peak regime of where the degrees of freedom maximize is where the Octonian regime holds.
2) Analog physics, prior to the buildup of temperature can be represented by Equation (17) and Equation (18).
References [
We acknowledge that Glinka, in [
m ≅ λ 2 / 5 ( 2 π 3 ) 2 / 5 ⋅ ( T P 3 / 2 ⋅ t P 50 / 32 ) 2 / 5 ≈ N graviton m graviton ⇒ N graviton ≈ S ( Entropyinitially ) ≈ λ 2 / 5 ( 2 π 3 ) 2 / 5 ⋅ ( T P 3 / 2 ⋅ t P 50 / 32 ) 2 / 5 m graviton (48)
What we find in doing this assuming that the cosmological constant does not change due to quintessence is that we have a much simpler entropy expression, which is commensurate with the formation of many massive gravitons being emitted initially and forming micro sized black holes. There is though a problem with this, in that the approach may require extreme fine tuning of λ which may or may not be justified. In doing this, we are making use of [
In addition [
Finally keep in mind that quintessence, varying initial vacuum energy will disrupt applying [
In all win some and lose some. It may be next impossible to reconcile octonionic structure with [
If so, by Novello [
m g = ℏ ⋅ Λ c (49)
as well as verifying [
m ≈ m P N gravitons M B H ≈ N gravitons ⋅ m P R B H ≈ N gravitons ⋅ l P S B H ≈ k B ⋅ N gravitons T B H ≈ T P N gravitons (50)
And by [
ϕ ( r ( t ) ) ~ ϕ ( t ) ≈ ( 50 / 32 ) ⋅ m P l ⋅ ln ( t ) (51)
Then according to [
U ( ϕ ) ~ − m 2 ϕ 2 + λ ϕ 4 (52)
Setting the temperature, T, and the time, t as Planck temperature and Planck time, and specifying we are still adhering to Equation (55) leads to a spontaneous symmetry breaking potential of the form which has λ
( 2.4 × 10 − 11 GeV / c 2 ) 4 ⋅ ( 1.2009 2 × 10 38 ( GeV ) 2 / c 4 ) ~ 4 π ⋅ λ 3 / 5 ( 2 π 3 ) 8 / 5 ⋅ ( T Planck 3 / 2 ⋅ t Planck 50 / 32 ) 8 / 5 (53)
Not using Octonionic gravity or space time may put a premium on the use of extreme fine tuning. This may be an experimental problem for data sets as the precision so forced may be beyond the scope of experimental detectors at this time.
This work is supported in part by National Nature Science Foundation of China grant No. 11075224.
The author declares no conflicts of interest regarding the publication of this paper.
Beckwith, A.W. (2023) Does the Transition to Planckian Space Time Physics Allow Octonionic Gravity Conditions to Form? Journal of High Energy Physics, Gravitation and Cosmology, 9, 561-581. https://doi.org/10.4236/jhepgc.2023.92047
The following formulation is to highlight how entropy generation blends in with quantum mechanics, and how the breakdown of some of the assumptions used in Lee’s paper coincide with the growth of degrees of freedom. What is crucial to Lee’s formulation, is Rindler geometry, which is flat space time geometry, not the curved space formulation of initial universe conditions. To enable these ideas, the following formulas are used from [
If gravity and Newton mechanics can be derived by considering information at Rindler horizons, it is natural to think quantum mechanics might have a similar origin. In this paper, along this line, it is suggested that quantum field theory (QFT) and quantum mechanics can be obtained from information theory applied to causal (Rindler) horizons, and that quantum randomness arises from information blocking by the horizons
To start this program, we look at the Rindler partition function, as given by [
Z R = ∑ i = 1 n exp [ − β H ( x i ) ] = T r a c e [ exp ( − β H ) ] (A1)
As stated by Lee [
Z Q = N 1 ∫ ℘ x ⋅ exp [ − i ℏ ⋅ I ( x i ) ] (A2)
where I ( x i ) is the action “integral” for each path x i , leading to a wave function for each path x i
ψ ~ exp [ − i ℏ ⋅ I ( x i ) ] (A3)
If we do a rescale ℏ = 1 , then the above wave equation can lead to a Schrodinger equation.
The example given by Lee [
H ( ϕ ) = ∫ d 3 x ⋅ [ 1 2 ⋅ [ ( ∂ t ϕ ) 2 + ( ∇ ϕ ) 2 ] + V ( ϕ ) ] (A4)
Here, V is a potential, and ϕ can have arbitrary values before measurement, and to a degree, Z represent uncertainty in measurement. In Rindler co-ordinates, H → H R , in co-ordinates ( η , r , x 2 , x 3 ) with proper time variance a r d η then
H R ( ϕ ) = ∫ d r d x ⊥ a r ⋅ [ 1 2 ⋅ [ ( ∂ ϕ ∂ r ) 2 + ( ∂ ϕ ∂ r ∂ η ) 2 + ( ∇ ⊥ ϕ ) 2 ] + V ( ϕ ) ] (A5)
Here, the ⊥ is a plane orthogonal to the ( η , r ) plane. If so then
Z = T r a c e [ exp ( − β H ) ] → Z R = T r a c e [ exp ( − β H R ) ] (A6)
Question: Can one transcribe Rindler co-ordinates to the “origin” of the big bang?
Provisional Answer: No. Also, Rindler co ordinates can be as good a description of present geometry. Note
F = − 1 β ⋅ ln Z R ≅ F ClassicaL ≈ [ I E ( x i ) ] (A7)
Here, F ClassicaL ≈ [ I E ( x i ) ] minimized, means that change in entropy is maximized. If we look at Verlinde entropy as associated with lost particle information, it means, if F = − k B T ⋅ ln Z ( T , V , N ¯ ) = − k B T ⋅ N [ ln ( V / λ 3 ) + 5 / 2 ] with λ 3 ≥ V , with V an initial space time volume, and λ the wave length, of say a graviton or equivalent space time particle at/about the origin, then one would have up to a point,
F = − 1 β ⋅ ln Z R ≅ F Classical ≅ ( I E ( x i ) ) ≈ − k B T ⋅ N [ ln ( V / λ 3 ) + 5 / 2 ] ≈ k B T N (A8)
Low temperature mean high entropy, and eventually, when one would get to the Planckian regime of space time, with the squeezing of space time geometry to a flat space Rindler geometry, the particle count algorithm
Δ S ~ n ( r e l l i c ) ~ # of initial relic particles (A9)
Here, having λ 3 ≥ V , with V the initial Planckian regime sized “volume” would be equivalent to the causal discontinuity relationship of a certain amount of “information” as given above above. Also, λ 3 ≥ V corresponds to having a filter for the creation of J effective ≅ n count ⋅ m 4-DGravtion , for “massive” gravitons.
Based upon [
For our early universe purposes, the main benefit of MUB would be in “encryption” of information [
This section is to high light the similarities and differences in entropy, in the pre Planckian regime, Planckian space time, and then in doing so, suggest inputs into experimentally detecting δ 0 . In a gravitational wave detector [
C1: Basics of Entropic relations
Let | ψ 〉 ε H n be a quantum state of n = log N qubits. Set B ≡ { | b i 〉 } i = 1 , ⋯ , n be an orthonormal basis in H n .
So, using the construction of an MUB as given in Appendix B, we can refer to | 〈 b | | b ′ 〉 | 2 = 1 / N for ∀ b ε B , b ′ ε B ′ , B ≠ B ′ ε β : with β a set of N + 1 MUB for H n .
C2: Theorem [Maasen-Uffink 88]
For any pair of mutually unbiased basis P and Q for H n , and | ψ 〉 ε H n , then, ∃ a probability distribution for
B ψ ( i ) = ‖ 〈 b i | ψ 〉 ‖ 2 (C1)
H ( B ψ ( i ) ) = − B ψ ( i ) log ( B ψ ( i ) ) (C2)
So now we go to the definition of Renyi entropy, i.e. for − 1 < α < ∞ defining the Renyi entropy of order α
H α ( B ψ ( i ) ) = − log ( ∑ i B ψ ( i ) 1 + α ) 1 / α (C3)
H 0 ( B ψ ( i ) ) = H ( B ψ ( i ) ) , H ∞ ( B ψ ( i ) ) = − log ( max i B ψ ( i ) ) (C4)
And now for the main result, i.e. the [Maasen-Uffink 88] theorem.
For any pair of mutually unbiased basis, P and Q for H n , and state | ψ 〉 ε H n then one has for logN = n quidbits
H ( P n ) + H ( Q n ) ≥ log N (C5)
This inequality involving zeroth order Renyi entropy as given by Equation (C4) should be contrasted with Ng [
A change of ~1013 orders of magnitude in about 10−25 seconds, or less in terms of one of the variants of inflation. As has been stated elsewhere [
D1: The relic GWs in the pre-big-bang model.
Here, the relic GWs have a broad peak bandwidth from 1 Hz to 10 GHz. We can refer to other such publications for equivalent information as in the pre big model [
D2: The relic GWs in the ekpyrotic scenario
Relic GWs in the ekpyrotic scenario [
D3: The relic GWs in the ordinary inflationary model
Also, for ordinary inflation [