What is the physical nature of gravitinos? As asked before, this question was the template of how to introduce Machian Physics as a way to link gravitinos in the electro weak era and gravitons as of the present. What we wish to do now is to ask how a flaw in the Higgs equation as brought up by Comay shows a branch off from orthodox quantum physics, leading to, with the Machs principle application done earlier a way to embed the beginning of the universe as a semi classical superstructure of which Quantum Mechanics is a subset of. We argue that this will necessitate a review of the Higgs equation of state for reasons stated in the manuscript. We also finally review a proprosal for another form of mass formation mechanism as a replacement for the Higgs mass as introduced by Glinka and Beckwith, 2012, with commentary as to how suitable it may be to get a gravitino mass in fidelity to the Machian proposal introduced by Beckwith previously, to get linkage between electroweak era gravitinos and present day gravitons.
We will ask the question here. In an earlier document, the author presented an equivilence between Gravitinos in the electro weak era, and Gravitons today. The motivation of using two types of Machs principle, one for the Gravitinos in the electro weak era, and then the 2nd modern day Mach’s principle, as organized by the author are as seen in [
are really a statement of information conservation. What we now ask is if the Gravitino can be re stated in terms in fidelity to quantum mechanics, or if some other theoretical constuction must be used. The motivation for asking this question will be seen in examining if the Gravitino, as in the mass in the left hand side of Equation (1), as it materializes due to Comay’s [
And
In fidelity with the physics evolution of
Whereas what is observed is, instead [
To further elucidate this question, we will also ask if there is a way to encapsulate in Equation (2) above in the methodology of constucting QM within a larger, semi classical theory. As given in the 5th Dice 2010 work shop, as given by Elze, Gambarotta and Vallone [
The end result is, after a Fourier transform re casting the Equation (6) in terms of a matrix equation looking like
We will discuss Equation (7) in a generalized incantation in APPENDIX A which will show as that the quantum mechanics type interactions require a most specialized potential, as either a constant, or a Harmonic potential, with others not sutiable, if we wish to extract quantum mechanics from the results of Equation (7), and from there to comment upon candidate equations which may be a way to contain as far as a generalized theory which may contain QM (Dirac) type behavior. If not, then Equation (2) does not qualify as far as having reduced to a quantum mechanica subset and we must then go to the Comay description of the Higgs equation used to define the creation of/evolution of the Gravitino as faulty physics, needing an abrupt fix to reduce it to the form of Equation (2) to salvage quantum mechanics.
Appendix B brings up the relevance of the Dirac eqjatkl to the critique which Comay [
In [
With a resulting Hubble rate for the radiation era as written as for, radiation era, as
The early Gravitino relic density is then given by an expression
times
This is, in terms of re heating temperature very close to linear in growth due to scaling with a re heating temperature. One obtains an approximately linear growth rate in terms of gravitino density with a most complicated Lagrangian density function which is in the top of Section 2.2. of [
The Machian hypothesis and actually Equation (10) are a way to address a serious issue, i.e. how to keep the consistency of physical law intact, in cosmological evolution [
Equation (10), which has neither a zero valued potential, a linear or a quadratic potential is clearly NOT in sync with the DICE 2010 Appendix A treatments leading to quantum mechanics, alone [
Equation (10) does NOT have fidelity with the sort of Comay criteria [
Either Equation (10) signifies that there is no match up with the sort of evolution equation (for creation of a Gravitino in the electro weak era) as exemplified by the Dirac Equation which Comay likes so much [
What we can look at is the Glinka-Beckwith [
We can treat the k as a wave “vector”, and look at the term as an energy term. Dependent upon how we interpret, i.e. as a per unit interpretation of energy, we could reconcile a treatment of a physically averaged out quantity of the potential energy as given in [
We can, to first order model the at in the Gravitino-matter field interaction as [
This Equation (12) is the potential energy term of Equation (2.82), page 22 of Josef Pradler’s [
Then, if we do Equation (13) in this spirit, we can then go to what Glinka-Beckwith wrote [
Terms such as
vanish from Equation(14).
Ultimately, the analysis of terms as specified in a gravitino-EW “matter” regime would specify the exact particulars as to Equation (12). We will also venture a first order approximate description as to why the mass of the Graviton in the later regime of space time, near the present would be so much smaller than the Gravitino.
Via use of the Glinka-Beckwith approximation for the formation of Mass, we have come up with a criteria where the Gravitino interaction with space-time physics in the electro weak, as outlined above, can be construed as either embedded within a larger theory than QM, as suggested by Elze et al. [
This work is supported in part by National Nature Science Foundation of China grant No.110752.
This discussion serves to bring up a Quantum like version of the Liouville equation and to from there to also make sense of the given equation, as of the main text [
To begin with, look at a generic Hamiltonian as given by
This Hamiltonian is incorporated in the Lioville equation of motion
The upshot if a Fourier transform is taken of Equation (A2) above, and the space like co-ordinates of
Equation (A1) then becomes
The term put in, namely which retrieves if we have classical or quantum information, and also, note
And
Then,
If so, then one can write
I.e. then we have that for the potentials represented by Equation (7), there is an overlap between classical and quantum versions of the Liouville equation as given by the Von Neuman equation as presented by
In so many words, we have a QM type situation guaranteed if Equation (A7) holds, whereas we can solve a more general theoretical construction in which there may be what is known as a super action given by
We then will be stuck with working with Equation (A4).
When the super action is reduced to, with Equation (A7)
To
We recover Equation (A9).
In short, the restrictions on the potential energy, as given by Equation (A7) are essential for the formation of quantum mechanics for exact quantum mechanical Hilbert space operators, whereas more general cases with.
Embedd quatum mechanics into the semi classical equation regime, as was specified by Elze and others.
We summarize the main point of Comay’s article [
The initial points of this borrowing from Comay have already been made in Equation (2) to Equation (5) so we will be discussing the action integral intepretation which Comay made, which was his primary way to differentiate between the faulty mathematics as he saw in the Higgs equation and the Dirac equation. We will reproduce his arguments as to that intepretation in this appendix.
Here, is a Lagrangian density function which is a Lorentz scalar, so then Equation (B1) is a Lorentz scalar.
The consequences that equation (B1) is a Lorentz scalar lead to several claims by Comay to follow upon and to use.
CLAIM 1:
1) A relativistically consistent quantum theory may be derived from Lagrangian density which is a Lorentz scalar.
2) An acceptable dimension for a Lagrangian density is of the form
3) A wave functional for both and cannot define a composite particle if is for a single four dimensional point in space time Sub claim to 3 above, and an effective re statement of 3 is: If were for a single ( not composite ) particle, then 3*. A: needs space time co-ordinates of its center of energy 3*. B: One needs additional co-ordinates for describing internal structure.
We shall then go to the next specific Comay Claim, namely CLAIM 2 Use the following procedure to get consistency of a quantum (massive particle) theory with a classical (massive particle) particle theory, namely by using the following field equation, as given by
For energy start off with the equation given by the 2nd order tensor, , with the energy density, and having dimensions, with
Sub set of CLAIM 2. In QM, the Hamiltonian is equal to the total energy, so we can write as the Hamiltonian density
Equation (B4) satisfies the continuity equation as given by
Then either of the two happen:
A. Hamiltionian density may be used to extract Hamiltonian H so that one can write a Hamiltonian so that then the following happens: Energy E is an eignvalue of
And the De Broglie functions hold as given by
So then the Hilbert space is formed using all of (completeness of the Hilbert space, using basis from).
OR B. Use expression for density to form inner product for inner product of and construct an orthormal baisis set ( often using Gram Schmitz orthoganization) for othnormal basis for corresponding Hilbert space.
Then, after B, to then look at a matrix equation given by
Form a matrix from Equation (B8), and then diagonalize this matrix to get eignvalues and ENERGY eignvectors .
ClAIM 3 Proceedures from CLAIM 1 and CLAIM 2, give the same eignvalues and eignvectors, SAME information.
CLAIM 4 The following Equations give almost the same information, one QM, and the other CM (Quantum versus Classical)
Applications of this formulation. See the Dirac Equation as given by Bjorken And Drell, [
This example works beautifully. Pion physics, Quark physics and more. There is an excellent match up with experiment.
Next application, Higgs equation, so that
Here we see then that
Specifically, for the Higgs, one has
Equation (B13) will then lead to a Higgs potential energy looking like, in simplest form. Where we only know the ratio of.
And we get a vacuum state given by
For the Higgs nucleation of mass, for a Graviton, we have a huge problem, i.e. many undetermined coefficients.
This is similar to what happens with Bjorken’s work [
Let be the Hubble rate of expansion of the cosmos, and set a scale factor as
Here we can re phrase as being the Hubble rate of expansion without torsion added in. Also
If we go to the Zeldovich relationship
Then we get a Lorentz violating “Lagrangian” added on term looking like, if
This Equation (B20) is a ten orders too small Lorentz violation term, in the Potential for a Lagrangian, for space-time emergence, but if it were larger, it would be similar in effect to the problem with the Higgs which Comay is outlining. Very close.