Unified Field Theory
American Journal of Modern Physics
Volume 2, Issue 6, November 2013, Pages: 292-298
Received: Sep. 25, 2013; Published: Oct. 30, 2013
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Authors
Zhiliang Cao, Wayne State University, 42 W Warren Ave, Detroit; Shanghai Jiaotong University, Shanghai, China
Henry Gu Cao, Deerfield High School, Deerfield, IL 60015, USA
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Abstract
The paper "SR Equations without Constant One-Way Speed of Light" [1] brings us a century back by discussing contradictory Relativity postulates. Instead of dealing with the aether theory, this paper proposes the Unified Field Theory (UFT) that replaces both the Theory of Relativity and Theory of Aether. In this new theory, the universe exists in form of Torque Grids in which Space, Time and Energy are unified. The ideal Torque Grids have same size and String movement cycle is the same as the Grid size in all directions. When Torque Grids have different sizes, the Torque Grids have size distortions. When Torque String movement speeds are different between two opposite directions, the Torque Grids have charge distortion. Both size and charge distortion can be measured by energy. The charge distortion can be measured by electronic charge in addition to the energy. The Gravity interactions and Strong interactions are related to Torque Grids’ size distortions. The electron-magnetic interactions and weak interactions are related to charge distortions. The Unified Field Theory derives the Planck equation and Newton’s gravity equation and explains why the electron is stable. The electron has a single Torque Grid distortion on its shell and is in resonance with its wavelength. Therefore, electron is stable and electronic field is formed. Strong force and weak force are result of two additional main resonance wave forms on the shell of the electron. Finally, the paper unifies the four fundamental fields.
Keywords
Unified Field Theory, Quantum Field Theory, Relativity, Dark Matter, Standard Model
To cite this article
Zhiliang Cao, Henry Gu Cao, Unified Field Theory, American Journal of Modern Physics. Vol. 2, No. 6, 2013, pp. 292-298. doi: 10.11648/j.ajmp.20130206.14
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