This book is dedicated to a clearer understanding of quantum mechanics, theory of relativity, gravitation, and electromagnetism, including essential phenomena as spin, the graviton spin, Black Hole, and the quantum particle states in the extreme conditions of a Black Hole formation, and of the Schwarzschild boundary. This understanding is based on our recent theory of the quantum particle dynamics as a distribution of matter propagating with the velocity of the waves, describing this distribution by a Fourier space-time series expansion, we call wave function. The mass quantization rule is obtained from the equality of the mass as the integral of the density with the mass as a dynamic characteristic, contained in the time dependent phases of the waves, which are proportional to the particle Lagrangian. This understanding is also based on Dirac’s formulation of the general theory of relativity, of our Universe as a hypersurface in the Total Universe. We present this theory in detail. For the electromagnetic field, we obtain the Lorentz force and the Maxwell equations from the condition of interaction with a quantum particle. A particle-antiparticle system is described as a wave packet of spinors with finite dimensions. Our Universe is understood as a huge Black Hole in the Total Universe, which, explains its properties, as the Big Bang, the inflation with a velocity much larger than the light velocity, the redshift of light coming from distant bodies, and the quasi-inertial state of a body very distant from the other bodies, in the theory of relativity framework.
About the Author:
Eliade Stefanescu graduated the Faculty of Electronics, Section of Physicist Engineers, in 1970, and obtained a PhD in Theoretical Physics in 1990. As a Scientist from 1976, a Senior Scientist III from 1978, he worked in technology of semiconductor devices. From 1978, he worked in physics of optoelectronic devices. From 1987, and from 1990 as a Senior Scientist II, he worked in the field of open quantum physics. In 1991 he discovered that the penetrability of a potential barrier can be increased by coupling to a dissipative system, and described the decay spectrum of some cold fission modes. As a Senior Scientist I, from 1997 he developed a microscopic theory of open quantum systems, and discovered a physical principle for the heat conversion into usable energy. In 2014, he produced a unitary relativistic quantum theory. In the years 1995-2000, he held a course called Dissipative Systems for the master degree.
Keywords:
Quantum Mechanics, Light velocity, Lorentz transformation, Curvature tensor, Lagrangian density, covariant acceleration, Geodesic equation, Electromagnetic field tensor, Dirac spin matrix, covariant normalization, Schwarzschild solution.
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