Can We Form Gravitinos by Something Other Than a Higgs Boson in the Electro-Weak Era?

ABSTRACT

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.

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.

Cite this paper

Beckwith, A. (2012) Can We Form Gravitinos by Something Other Than a Higgs Boson in the Electro-Weak Era?.*Journal of Modern Physics*, **3**, 1255-1260. doi: 10.4236/jmp.2012.329162.

Beckwith, A. (2012) Can We Form Gravitinos by Something Other Than a Higgs Boson in the Electro-Weak Era?.

References

[1] A. W. Beckwith, “Gravitons, Gravitinos, and Using Machs Principle to Make a Statement of Equivalent Information in a Gravitino-Graviton Correspondence of Critical Information Exchange from Electro-Weak to Present Era,” http://vixra.org/abs/1204.0089

[2] E. Comay, “Physical Consequences of Mathematical Principles,” Progress in Physics, Vol. 4, 2009, pp. 91-98.

[3] H.-T. Elze, G. Gambarotta and F. Vallone, “General Linear Dynamics-Quantum, Classical or Hybrid,” IOP Conference Proceedings of the DICE 2010 Meeting, 2010. http://iopscience.iop.org/1742-6596/306/1/012010

[4] J.-W. Lee, “On the Origin of Entropic Gravity and Inertia,” Foundations of physics, Vol. 42, 2012. http://arxiv.org/abs/1003.4464

[5] J. Pradler, http://arxiv.org/pdf/0708.2786.pdf$$yThesis

[6] A. Beckwith and L. Glinka, “The Quaternionic Particle Mass,” Prespacetime Journal, Vol. 3, No. 2, 2012, pp. 126-130.

[7] K. Hinterbichler, “Theoretical Aspects of Massive Gravity,” http://arxiv.org/abs/1105.3735.pdf

[8] http://web.mit.edu/redingtn/www/netadv/Xgravitati.html

[9] G. t’Hooft, “Quantum Mechanics as a Dissipative Deterministic System,” http://arxiv.org/PS_cache/gr-qc/pdf/9903/9903084v3.pdf

[10] J. Bjorken and S. Drell, “Relativisitic Quantum Mechanics,” McGraw Hill, 1964.

[11] J. Bjorken, “Emergent Photons and Gravitons: The Problem of Vacuum Structure,” arXIV 1008.0033 v1[hep-th], 2010.

[1] A. W. Beckwith, “Gravitons, Gravitinos, and Using Machs Principle to Make a Statement of Equivalent Information in a Gravitino-Graviton Correspondence of Critical Information Exchange from Electro-Weak to Present Era,” http://vixra.org/abs/1204.0089

[2] E. Comay, “Physical Consequences of Mathematical Principles,” Progress in Physics, Vol. 4, 2009, pp. 91-98.

[3] H.-T. Elze, G. Gambarotta and F. Vallone, “General Linear Dynamics-Quantum, Classical or Hybrid,” IOP Conference Proceedings of the DICE 2010 Meeting, 2010. http://iopscience.iop.org/1742-6596/306/1/012010

[4] J.-W. Lee, “On the Origin of Entropic Gravity and Inertia,” Foundations of physics, Vol. 42, 2012. http://arxiv.org/abs/1003.4464

[5] J. Pradler, http://arxiv.org/pdf/0708.2786.pdf$$yThesis

[6] A. Beckwith and L. Glinka, “The Quaternionic Particle Mass,” Prespacetime Journal, Vol. 3, No. 2, 2012, pp. 126-130.

[7] K. Hinterbichler, “Theoretical Aspects of Massive Gravity,” http://arxiv.org/abs/1105.3735.pdf

[8] http://web.mit.edu/redingtn/www/netadv/Xgravitati.html

[9] G. t’Hooft, “Quantum Mechanics as a Dissipative Deterministic System,” http://arxiv.org/PS_cache/gr-qc/pdf/9903/9903084v3.pdf

[10] J. Bjorken and S. Drell, “Relativisitic Quantum Mechanics,” McGraw Hill, 1964.

[11] J. Bjorken, “Emergent Photons and Gravitons: The Problem of Vacuum Structure,” arXIV 1008.0033 v1[hep-th], 2010.