Octonionic Gravity Formation, Its Connections to Micro Physics

doi:10.4236/ojm.2011.11002

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Open Journal of Microphysics, 2011, 1, 13-18

doi:10.4236/ojm.2011.11002 Published Online May 2011 (http://www.SciRP.org/journal/ojm)

Octonionic Gravity Formation, Its Connections to

Micro Physics

Andrew Beckwith

Department of Physics, Chongqing University, Chongqing, China

E-mail: abeckwith@uh.edu

Received March 14, 2011; revised May 1, 2011; accepted May 11, 2011

Abstract

We ask if Octonionic quantum gravity is a relevant consideration near the Planck scale. Furthermore, we

examine whether gravitational waves would be generated during the initial phase, 0



, of the universe when

triggered by changes in spacetime geometry; i.e. what role would an increase in degrees of freedom have in

setting the conditions during 0



, so that the result of these conditions can be observed and analyzed by a

gravitational detector. The micro physics interaction is due to the formation of a pre Planckian to Planckian

space time transition in spatial dimensions at and near the Planck dimensional values, i.e. 10–33 centimeters in

spatial dimensions. This transition would be abrupt and arising in micro physics regimes of space time.

Keywords: High-Frequency Gravitational Waves (HFGW), Symmetry, Causal Discontinuity

1. Introduction

The Planck epoch has remained mysterious, and may be

invisible to all other kinds of detectors, but the universe’s

gravity wave background radiation likely contains the

imprint of even the very earliest events. Changes in the

geometry of space-time near the Planck scale could be

revealed or studied in this manner. We discuss how to

obtain insights into 0



, initially, while looking at the

geometric considerations determining space and time

development which would create relevant space-time

geometry phase changes during the early universe. The

formation of Planckian space time is in what is called

Octonionic quantum gravity [1] Each such phase change

leading to Octonionic Quantum gravity should produce

gravitational waves. The geometry change alluded to is

effectively initially on an infinitesimal scale, which is

why Micro physics is referred to at all. (‘quantum me-

chanics’) and de facto quantum gravity, at the start of

Planckian space time. This Planckian space time would

mark the beginning of inflation. We give conditions for

detection of [2,3] 0



if, for example, one can isolate an

appropriate first-order perturbative electromagnetic power

flux, [2-4] in scenarios where the graviton has a

(1)

vanishingly small – but non-zero – rest mass [2]. Now

for how to get non zero graviton rest mass. This is where

the micro physics regime becomes so important.

The Micro Physics Problem. How to Solve the Corre-

spondence Problem, I. E. (Gravitons in 4D with Slight

Mass (5 Degrees of Freedom) Versus Gravitons in 4 D

with NO Mass (2 Degrees of Freedom).

This formation of a graviton, must be done before the

formation of QM, in space time.

The correspondence problem, is that a Graviton with

slight rest mass in 4 D will have five degrees of freedom

wheras a Graviton in 4 D, with no mass has two degrees

of freedom. I.e. there is no way about this, and that if

gravitons as brought up by Beckwith [2] have a small

rest mass, which contributes to DE speed up of accelera-

tion of the universe a billion years ago, gravitons cannot

be synthesized during the time when QM becomes

dominant. This document gives a regime of space time

before QM, which embeds quantum mechanics. If a 4D

graviton with rest mass not equal to zero is formed, it

will be in the template of space time before to up to 10–44

seconds. I.e. as stated , so as to have GW/Gravitons with

rest mass not equal to zero forming [2], The document

mentions a phase alteration, which we claim is due to

this alteration from classical embedding of quantum me-

chanics, to its full expression in the Planckian space time

regime. This micro physics leads to [2-4] 0



What we propose is the following evolution in the mi-

cro physics regime, up to 10–44 seconds

1) That the degrees of freedom increase, with an in-

A. BECKWITH

crease in temperature, during a transition to a Rindler

Geometry flat space regime of space time. As given

in Equation (16), with increasing temperature, more

degrees of freedom unfold from a topological transi-

tion. Degrees of freedom likely approach a maxima

as temperature does, but this is a subject needing ex-

perimental exploration and verification.

2) That for low but non zero initial temperature, the so

called cold universe model, in pre space time in the

pre Planckian regime, one has initially a huge degree

of generated entropy. At the same time, we have

about 2 degrees of freedom, with complex geometry

in each geometrical slot, geoinfometric instantiation,

or “infometron” of space time, which large quantities

of stored entropy enveloped in the ‘crevices’ between

infometrons, or lattice points.

3) Low degrees of freedom for low temperature corre-

sponds to a complex geometry storing large amounts

of total entropy in a complex geometric structure, and

that later the entropy is released, with a break down

of this complex geometric structure, i.e. equivalent to

having many lattices, highly ordered, with low de-

grees of freedom per ‘lattice’, to many degrees of

freedom (DOF) as space time ‘lattices’ are broken,

releasing entropy. The analogy is not perfect, but ap-

proximates what would happen as one goes from

complex curved space geometry with many ‘crevices’

for storage of entropy, which are released, “appar-

ently” leading to a lot of entropy,.

Further elaboration of what is being brought up is tied

in with mutually unbiased basis (MUB), [5] .The values

of 0



are set by the difference between Renyi entropy

[6], and a particle count version of entropy, i.e. Sn.

Are predictions also possible regarding signal strength of

evolutionary artifacts of early universe HFGW? Again,

yes. What we are talking about is the break down, due to

thermal heat flux of an initial mutually unbiased basis set

for a very complex initial geometry, and a reconstitution

of space time geometry in flat Euclidian space time re-

gime. The topological transition is due to a change in

basis / geometry from the regime of Renyi entropy [6]to

entropy in a particle count version of entropy, i.e. Sn.

The choice of a Gaussian mapping, with two variable

inputs, as given by Equation (16) below is done as a

simplest case model. We will model inputs into the ini-

tial value of as high energy fluctuations, and see if

they contribute to examination of the formation of non

commutative geometry in the beginning/just before the

inflationary era.



1.1. First, Thermal Input into the New Universe.

In Terms of Vacuum Energy

We will briefly allude to temperature drivers which may

say something about how thermal energy will be intro-

duced into the onset of a universe. This will be the

‘thermal driver’ for the increase in degrees of freedom.

Begin first with looking at different value of the cosmo-

logical vacuum energy parameters, in four and five di-

mensions [7]



5dim1 1cT







 (1)

in contrast with the more traditional four-dimensional

version of the same, minus the minus sign of the brane

world theory version. as given by Park [8]

4dim 2







 (2)

Right after the gravitons are released, one still sees a

drop-off of temperature contributions to the cosmological

constant .Then for time values1





, and

integer n [7]





4dim

5dim





 (3)

In terms of its import the following has been suggested

in the initial phases of the big bang, with large vacuum

energy



 and





0, 01at at



 , the following

relation, which violates (signal) causality, is obtained for

small fluctuation





at l





If we examine



5dim 2



We assume in this that we have, a discontinuity in the

pre Planckian regime, for scale factors [7].









1( )1

at tval ue















 





 (4)

Furthermore, in the transition for 0

tt the fol-

lowing increase in degrees of freedom is driven by ther-

mal energy from a prior universe starting with [9]

thermalB temperature

EkT T











 (5)

The assumption is that there is an initial fixed entropy

arising, with N as a nucleated structure in short time

interval as temperature ar-

rives.



0,10

temperature



eV

If the inputs into the inflaton



, as given by a random

influx of thermal energy from temperature, we will see

the particle count on the right hand side of Equation (13)



1612161

24π4π4π

Planck

STk M

































































 (6)

A. BECKWITH15

above a random creation of

article Count

n

e degrees of

. The way to

introduce the expansion of thfreedom from

3 is to definearly zero to having N(T) ~ 10ne the classical

and quantum regimes of gravity as to minimize the point

of the bifurcation diagram affected by quantum processes

[9]. Dynamical systems modeling is employed right ‘af-

ter’ evolution through the ‘quantum dot’ regime. The

diagram, would look like an application of the Gauss

mapping of [9].

expxx

1ii













 (7)

The inputs of change of iterated st

hand side of Equation (14) may indeed s

eps on the right

how increase in

grees of freedom. Change of temperature, as given,

over a short distance, is [5,6]



temp

dist di



 



netelectricfield

st 

change in degree of freedom



(8)

We would regard this as being the regime in which we

see a thermal increase in temperature, up to the Planckian

Temperatures as Given in Table 1 Leads to

To d[1] as to how to look at the way we

may have , if temperatures increase, as stated in Table 1

ysics regime. If so, then we can next look at what is

the feeding in mechanism from the end of a universe, or

universes, and inputs into Equation (7), Equation (8).

1.2. Formal Proof that Increase in Thermal

Approaching Quantum Mechanics, As a

End Run about the Correspondence

Problem.

o this we look at

above, from a low point to a higher one, for there to be a

flattening of space time and the end of non communative

geometry. This non communative geometry due to rising

temperatures signifies conditions for the emergence of

Equation (23) to become [1]

xpi ij









  (9)

In order to get conditions for Equation

lowing can be referred to about non comm

smological in 5 and 4 dimensions [7], with

phasis upon the Michysics initial regime.

(24) the fol-

utative ge-

etry [1]

Table 1. Co

ro pem



0P

(PLANCK TIME ~ 10–44 S CONDS).

Time0

tt Time 0



 Time

tt

 undefined,

T



32

10T

almost

jiji Temp

xx i





 

 (10)

The essentials step is to imetric rl

tensor is proportional to the square of 1 over the Parks

representation of the “Planck constnt”, which has a

temperature dependence built in it [1].

say the ant symea



~~ 10

ji NCDimT











 

 (11)

When Equation (26) goes to zero, leading to Equation

(10) going to zero, we submit that then Equation (10) is

recovering quantum/Octonian gravity. The Equation (24)

is linkable to initial violations of Lorentz invaria

submit that the entire argument of Equation (22) to

Emergent Structure Cosmology

and wave

gene given

by Led in Chong-

quing the following representation of amplitude, i.e. as

nce. We

uation (25), as given by Equation (11) with rising

temperature is a way to understand the removal of non

Euclidian space to approach Euclidian flat space. We shall

next examine how this increasing temperature may lead to

an explosion of the degrees of freedom present.

1.3. Understanding how Phase Shift in

Gravitational Waves may be Affected by the

Transition to and from a Causal

Discontinuity, and Different Models o

will outline research initiated by . Beckwith and Li,

Yang Nang, gives us details of gravitational

ration by early universe conditions. In [3] as

i, and Yang, 2009, Beckwith [2] outlin

by reading [3] the following case for amplitude







(12)

Furthermore, the first order perturbative (E and M)

terms of an E&M field may have its components written

as [3]

(1)

0 20

(1)

iF



(13)

Secondly, there is a way to represent the” number” of

transverse first order perturbative photon flux density as

given by (in an earth bound high frequency GW detector).

[3]



(1)





 (14)







(1)*

0 1

exp y

iiF yx



























 (15)

Here the quantity



















4dim

 





 ,

extremy

large

4dim

 el

32 12

10 10

T K

 ,

dim



T much smaller

than 10

TK12

represents the

z component of the magnetic field of a Gaussian b

be used in an EM cavity to detect GW. We introduce the

eam to

A. BECKWITH

quy factor of the dete

antity Q, the qualitctor cavity set up

observe GW, and



, the experimental GW amplitude.

In the simplest case, (0)

B is a static magnetic field.

Then the (1) (1)

0 20 1

iF



will lead to [2,3]

(1) (0)

0 10

2snexp

FiABQit







rmula



 











 (16)

The fo1

aB temperature

kT

therm l





is a feed

into



provided that we pick time Planc

and set Equation (16) with

tk time,



 by setting up the

thermalB temp

erature



ds, for relic 



[9]. In other wor

raranGW/gviton production, a topological tsformation and

interrelationship between



 and

thermalB temperature

EkT







for increases in (topologi-

cal) degrees of freedom, as a change in geometry, i.e.

before quantum gravity. Passing gravitons through to a

new univis not the same thinerse g though as a pre

Planckian geometry, f or Octonian gravity conditions

arise in early Planckian space time. This is a different

perspective than what is normally used in analyzing what

happens in a transition between initial Planck time ~

10 seconds, and cosmological evolution up to 30

10

seconds We will specify how to locate massive gravitons,

via an experimental set up which may enable obtaining

data for supporting a value [2,3] for 0



. The next dis-

cussion is on research done by Dr. F. Li, et al., 2003, [4],

2. Re Casting the Problem of GW/Graviton

in a Detector for “Massive” Gravitons

We now turn to the problem of detection. The following

sea time

discussion is based upon with the work of Dr. Li, Dr

Beckwith, and other Institute of theoretical physics re

rchers in Chongquing University [2-4]. It is now

to consider what happens if one is looking for traces of

gravitons which may have a small rest mass in four di-

mensions. What Li et al. have shown in 2003 [2-4] which

Beckwith commented upon and made an extension in [2]

is to obtain a way to present what is called here in the

literature [3,4]a first order perturbative electromagnetic

power flux, i.e. what was called

(1)

Tin terms of a non

zero four dimensional graviton rest mass, in a detector ,

in the presence of uniform magnetic field, when exam-

ining the following situation, i.e. [2-4] what if we have

curved space time with say an ener momentum tensor

of the electro magnetic fields in GW fields as given by

uvv v

TFFgFF











 





(17)

Li et al. [3,4] state that (0) (1)

vv v







, with

(1) (0)



 will lead to

(0) (1)

uvuv uv uv

TTTT

(2)





The 1st term to the right hand side of Equation (18) is

thf the back groun

tro magnetic 2 term to the right hand side

of Equation (18) is the first order perturbation of an elec-

tro magnetic field due to the presen

(18)

e energy – momentum tensor od elec-

field, and the nd

ce of gravitational

aves. The above Equation (17) and Equation (18) will

eventually lead to a curved space version of the Maxwell

equations as [3]





ggF J



 







 



 (19)

as well as





 (20)

Eventually, with GW affecting the above

ve a way to isolate If one looks at if a

sional graviton with a very small rest mass

included [2-4] we can write[2] an

[3,4]

two equa-

tions, we ha

four dimen

(1)

extension of Li et al.





0effecti ve

vgggFJJ





 



 



 (21) 

where for 0







but very small [3,4]









 (22)

The claim which A. Beckwith made [2] is that

4effectivecountDGravition

Jnm



 (23)

As stated by Beckwith, in [2],

grams, while

tenut an appropriate

as ass, and u

410

DGravition



 

count

n is the number

gravitons which may be in the detector sample. What

ckwith, Li, and Chonquing university researchers in-

d to do is to try to isolate o

suming a non zero graviton res

(1)

t msing Equa-

tion (21), Equation (22) and Equation (23). From there,

the energy density order contributions of,

(1)

T i.e.

(1)

can be isolated, and reviewed in order to obtain traces





, which can be used to interpret Equation (14). I.e. use







and make a linkage of sorts with

(1)

T. The term

(1)

T isolated out from

(1)

T present day dhe ata. Tpoint

be to cosen

of diffe

Working with a unified The value picked for

here that the detected GW would help constrain and

lidate Equation (14). If this is done, the next step will

me up with a protocol as far as making se out

rent GW measurement protocols.

0GW

h.

A. BECKWITH17

2.1. Wavelength, Sensitivity a

] treatment of both wavelength,

early

serve,

suchle of

earlyation of GW at the

generaleasurements was

0~10

h

 (24)

Next, after we tabulate results with this measurement

standard, we will commence to note the difference and

the variances from using 26

0~10

h

 as a unified

measurement which will be in the different models dis-

cussed right afterwards

nd other such

Constructions from Maggiore, with our

Adaptations and Comments

We will next give several of our basic considerations as

to early universe geometry which we think are appropri-

ate as to Maggiore’s [10

strain, and GW

 among other things. As far as

universe geometry and what we may be able to ob

considerations are make or break as to the ro

universe geometry and the gener

start of the universe. To begin with, we will look at

Maggiore’s [10] GW

 formulation, his ideas of strain.

The idea will be to look at how the ten to the tenth

stretch out of generated wave length may tie in with

early universe models. We will from there proceed to

look at, and speculate how the presented conclusions

factor in with information exchange between different

universes.

We begin with the following tables, Table 1 and Ta-

ble 2. The idea will be to, if one has 00.51 0.14h, as

a degree of measurement uncertainty begin as to under-

stand what may be affecting an expansion of the wave

lengths of pre Planckian GW/gravitons which are then

increased up to ten orders of magnitude. What we have

stated below in Table 2 will have major consequences as

far as not only information flow from a prior to present

universe, but also fine tuning the degree of GW variance

What we are expecting, as given to us by L. Crowell,

is that initial waves, synthesized in the initial part of the

Planckian regime would have about 14

~10

GW meters





for 22

~10

Hertz which would turn into

~10

GW meters



, for 9

~10

Hertz, and sensitivity

Table 2. Managing GW generation from pre planckian

physics and its immediate aftermath.

2.82 10

h

 12

~10

Hertz 4

~10

GW meters





2.82 10

h

 10

~10

Hertz 2

~10

GW meters





2.82 10



 h8

~10

Hertz 0

~10

GW meters



2.82 10

h

 6

~10

Hertz 2

~10

GW meters



2.82 10

h

 4

~10

Hertz 1

~10

GW kilo meter



23 2

2.82 10

h

 ~10

Hertz 3

~10

GW kilometer



2.82 0

h. This is assuming that 2

h of 1





6GW

~10



, using Magg

. It is por

discuss the differen

iorie’s [10] analy

tant to note

t models th

0GW

h

i all of this, th

at the

tical

at when

ex-

pression imn

we 0

h10





is drastically al-

n (26

eality, on

, the fi

) should

ly the

pe being seri-

ons of

rst col-

is th

tered

2nd

e first mesurem

. C

h which is m

also noted t be

and 3rd columns in

ly off and very

vita

aent metr

entioned i

an upper b

Table 1

ic which

Equatio

ound. In r

above esca

quark

ous different., since the interacti

grational waves/gravitons with – gluon plas-

mas and even neutrinos would serve to deform by at least

an order of magnitude C

h. So for Table 1

umn is meant to be an upper bound which, even if using

Equatio(40.c) may be off by an order of magnitude.

More seriously, the number of gravitons per unit volume

of phase space as estimated, is heavily dependent upon

0~10



.

The particle per phase state count will be given as, if

0~10



 [10]

10 1000

~3.6

fGW

nh f



 





(25)

Secondly we have that a detector strain for device

physics is given by [10]



21 1

2.82 10







(26)



These values of strain, the numerical count, and also

ssibl

give a bit count and entropy which

poe limits as to how much information is trans

will lead to

rred. Note that the beginning of relic inflation GW



~10 10

meters n

 /graviton unitphase 

space

for ~10

Hertz

in pre inflationary physics of

This is to have, say a starting point

10~

Hertz when

~10

,

GW meters i.e. a change of ders of

magnitude in about 25



~10 or



seconds, or less.

3. 1st Part of Conclusion. Can We Justify/

Isolate out an Appropriate if one ha

on Zero Gra

It is difficult. It tandi

strucat the mathe-

matical self organized criticality structure is akin to a

fla-

Wh itting

(1)

T s

Nviton Rest Mass?

depends upon undersng what is

meant by emergent ture, we assert th

definition as to how Dp branes arise at the start of in

tion. at is the emergent structure perm

,ik ik

pdx









to hold? [1] What is

ticality structure leading to forming an

the self organized

cri appropriate

(1)

T if one has non zero graviton rest mass? Answering

such questions will permit us to understand how to link

A. BECKWITH

finding

(1)

T in a GW detector, its full analytical link-

age to



in Equation (16). The following construction

is used to elucid

GW detector. This construction below is to be used to

inve

/gra

ity

space timrresponds, as brought up in the

chni-

cal assistance to the author as to understanding the phase

s due to early universe cos-

gnificant encouragement to

[2] A. W. Beckwith, “Identifying a Kaluza- Klein treatment

permitting a de-celeration parameter Q(Z)

e to standard DE “,Journal of Cosmology,

104008

018-1026, 2008

n Brane

Use the Cosmological

ate how a EM Gaussian sense beam can

(1)

perhaps be used to eventually help in isolating uv

T in a

stigate ‘massive gravitons’/and also the initial struc-

ture of self organized criticality, in the aftermath of

gravitonvitational wave generation.

3.1. 2nd Part of Conclusion: In Terms of the

Planckian Evolution and a Pre Planckian

Space Time

We wish to summarize what we have presented in an

orderly fashion. Doing so is a way of stating that Analog,

(Pre Ocononian) reality is the driving force behind the

evolution of inflationary physics

1) Pre Octonian gravity physics (analog regime of

ity) features a break down of the Octonian grav

ommutation relationships when one has curve

e. This co

real-

Volume 13, 2011,

http://journalofcosmology/BeckwithGraviton.pdf

[3] F. Li, and N. Yang, “Phase and Polarization State of High

d Fr

Jacobi iterated mapping for the evolution of degrees

of freedom to a build up of temperature for an in-

crease 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 Octo-

nian regime holds.

2) Analog physics, prior to the build up of temperature

can be represented by Equation (7) and Equation (8).

The first of these mappings is an ergotic mapping, a

perfect mixing regime from many universes into our

own present universe. This mapping requires a de-

terministic quantum limit as similar to what t’Hooft

included in his embedding of Quantum physics in a

larger, non linear theory [11].

This will help to localize the regime of space time

build up potentially giving experimental details to the

formation of Equation (14) and Equation (15) above. The

claim is that the physical evolution described by Equa-

tion (7) and Equation (8) would arise, as a dynamic evo-

lutionary process in the Micro physics regime leading to

an embedding of quantum physics, in a larger, non linear

theory, which would lead to massive gravitons being

nthesized whole scale. This whole scale synthesis of

gravitons with a small rest mass occurs in initial micro

physics background as indicated above, a result we hope

to confirm via accurate measurements of the phase.

4. Acknowledgements

This work is supported in part by National Nature Sci-

ence Foundation of China grant No. 11075224 Dr Fan-

gyu Li of Chongquing University gave extensive te

change in gravitational wave

mology. Stuart Allen gave si

the author as to finalizing this document for publication.

5. References

[1] L. Crowell, Quantum Fluctuations of Space-time, in

World Scientific Series in Contemporary Chemical Phys-

ics, Volume 25, Singapore, Republic of Singapore, 2005.

of a Graviton

as an alternativ

equency Gravitational waves”, Chin Phys. Lett. Vol

236, No 5(2009), 050402, pp 1-4

[4] F. Li,. M.,Tang, D. Shi, “Electromagnetic response of a

Gaussian beam to high frequency relic gravitational waves

in quintessential inflationary models”, PRD 67,

(2003), pp1-17

[5] S. Chaturvedi, “Mutually Unbiased Bases”, Pramana

Journal of Physics, Vol. 52, No. 2, pp 345-350

[6] John C. Baez, “Renyi Entropy and Free Energy”,

http://arxiv.org/abs/1102.2098

[7] A. W. Beckwith, arXiv:0804.0196 [physics.gen-ph], AIP

Conf.Proc. 969:1

[8] D. K., Park, H. Kim, H., and S. Tamarayan, “Nonvanish-

ing Cosmological Constant of Flat Universe i

world Senarios,” Phys. Lett. B 535, 5-10 (2002).

[9] A. W. Beckwith,” How to

Schwinger Principle for Energy Entropy, and “atoms of

Space-Time” to Create a Thermodynamic Space-Time

and Multiverse”; accepted for the DICE 2010 proceed-

ings; http://vixra.org/abs/1101.0024, 2010

[10] M. Maggiorie,. “Gravitational Wave Experiments and

Early Universe Cosmology”, Physics Reports 331 (2000)

pp. 283-367

[11] G. t’ Hooft, Beyond the Quantum, edited by Th. M. Nieu-

wenhuizen et al. Singapore, World Press Scientific, 2006;

http://arxiv.org/PS_cache/quant-ph/pdf/0604/0604008v2.

pdf.