Quantum Wave Mechanics Ch 33 Gravitation (original) (raw)
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Collection of scientific works of Odesa Military Academy, 2021
It is shown that gravitating objects that are at rest, or move without acceleration, create a standing gravitational wave in space. The length of this wave is a quantization step of the gravitational field. It is proportional to the mass of the gravitating object. The coefficient of proportionality is a value that is inverse to the linear density of the Planck mass, that is, proportional to the linear rarefaction of the Planck mass. A physically standing gravitational wave is a curvature, deformation of space under the influence of the gravitational field of a gravitating object. If we imagine a gravitating object as a material point, then the geometric picture of a standing gravitational wave can be represented as a set of hierarchical spherical equipotential surfaces embedded in each other, the radius of which changes away from the center of gravity by the value of the quantization step. It is shown that a standing gravitational wave has a quantum character. The quantum of the gravitational field is the square of the speed of light in a vacuum. The quantum of the gravitational field is equal to the gravitational potential of the gravitating object at a distance from it equal to the quantization step. Theoretical and experimental substantiation of the presence of gravitational-electromagnetic resonance (GER) in nature is given. This resonance arises when the wave vectors of a standing gravitational wave and an electromagnetic wave traveling in space are equal. GER is the basis for modulating the emission spectrum of stars and their clusters. The wavelength of the envelope of the spectrum is proportional to the mass of the radiating object. By measuring the wavelength of the envelope, one can accurately estimate the mass of the radiating object. The physical nature of the quantum gravitational field is the kinematic gravitational viscosity of the gravitational field of the baryonic matter of the observable Universe.
Quantum Wave Mechanics Ch 34 Gravitation as a Harmonic Phenomena
Quantum Wave Mechanics 4th ed., 2022
Something completely new has to be found…something that is somehow based on the ideas of General Relativity. - Albert Einstein A mass object represents an ensemble of one or more autonomous, individual, periodic, self-sustained oscillators (e.g., electrons, atoms, etc) radiating a broad spectrum of electromagnetic waves. Oscillators constitute clocks which are formed of standing matter waves. In synchronicity, the coupled oscillators reset to common base frequency. Clocks (and standing waves) undergo Lorentz contraction in the direction of motion, slow down in motion, and undergo a time shift due to Lorentz-Doppler effect. In free-fall, the frequency discordance is reduced to zero whereas at a fixed elevation potential, the oscillators are prevented from approaching synchronicity with a net acceleration equivalent to the net frequency difference. Standing wave interference of coupled oscillators can result in repulsion, attraction or cancellation depending on phase difference. Motion of matter arises as a result of dissonance in which the wave system is attracted to wave anti-nodes of out-of-phase oscillator pairs in alternating push/pull fashion.
Quantum Wave Mechanics Ch 42 Newtonian Gravitational Force
Quantum Wave Mechanics 4th ed., 2022
Calculation of the gravitation force between electrons according to the Macken model is described in terms of strain amplitude relating the nonlinear vacuum energy resonance at the Compton and Planck scales. Diagrams of the vacuum nonlinearity and electron vacuum resonance are illustrated. Electric charge results from a slight spin precession of the electron with whirl no. equal to the inverse fine structure constant. Electrostatic and gravitation force between electrons are compared. Gravitation force arises as a result of a gradient in the EM spectral energy density gradient. Both light and matter are subject to gravitational scalar and vector potential effects. The generalized Newtonian force equation advanced by Jefimenko includes scalar and vector potential components. The gravitational vector potential is proportional to the velocity of the gravitational scalar potential. The gravikinetic field opposes changes in mass motion. Photon wave function interference produces an effective mass due to change in momentum in regions of increased EM energy density. Similarly, matter wave interference is responsible for relativistic mass increase of a moving standing wave due to change of momentum in regions of increased EM energy density.
It is shown that gravitating objects that are at rest, or move without acceleration, create a standing gravitational wave in space. The length of this wave is a quantization step of the gravitational field. It is proportional to the mass of the gravitating object. The coefficient of proportionality is a value that is inverse to the linear density of the Planck mass, that is, proportional to the linear rarefaction of the Planck mass. A physically standing gravitational wave is a curvature, deformation of space under the influence of the gravitational field of a gravitating object. If we imagine a gravitating object as a material point, then the geometric picture of a standing gravitational wave can be represented as a set of hierarchical spherical equipotential surfaces embedded in each other, the radius of which changes away from the center of gravity by the value of the quantization step. It is shown that a standing gravitational wave has a quantum character. The quantum of the gravitational field is the square of the speed of light in a vacuum. The quantum of the gravitational field is equal to the gravitational potential of the gravitating object at a distance from it equal to the quantization step. Theoretical and experimental substantiation of the presence of gravitational-electromagnetic resonance (GER) in nature is given. This resonance arises when the wave vectors of a standing gravitational wave and an electromagnetic wave traveling in space are equal. GER is the basis for modulating the emission spectrum of stars and their clusters. The wavelength of the envelope of the spectrum is proportional to the mass of the radiating object. By measuring the wavelength of the envelope, one can accurately estimate the mass of the radiating object.
A quantum oscillator that could explain gravity
Inertial propulsion is experimentally demonstrated based on the linear asymmetric stretch oscillation of a free piston. Making the assumption that the known vibration of the atomic nucleus has an asymmetrical component, a nuclear self-propulsion analogue to the above free piston experiment may explain the continuous and random movement of molecules in a gas. Gravity could be described as a pushing force, instead of a pulling force. Two masses are pushed toward each other by asymmetric stretch nuclear quantum vibrations. Newton's law of gravity could be also amended as it appears that the temperature of each object affects the gravitational force. The gravitational push can be explained through a reorientation (gravitational "polarization") of individual nuclear asymmetric stretch oscillators in the direction of the line between the centers of mass, called gravitization, a term coined in similarity with magnetization. Gravitization also triggers entropic processes such as cryogravity and gravitational memory. Therefore gravity appears to be a cooperative mix of quantum and electromagnetic processes with entropic consequences. The contribution of this article is to provide an intuitive, yet powerful model that shows that gravitational and electromagnetic forces have important similarities. Moreover, this model goes beyond gravity and puts inertia, the gravitational potential energy, dilation of matter, length contraction and the speed limit in the universe in a new light.
Wave Dynamics of Quantum Gravity-Space
Gravity-Space phenomenon is observed as unique, wavy, nonlinear and even a-temporal by its nature. A wave function describing the state of space encircling a gravitodynamic vortex is suggested. Linear vector gravity would be a realistic linear approximation. In the “strong field” limits, a quantization of orbits should be quite natural and fully observable. That phenomenon is named gravitonium. Quantum gravitomagnetic resonance with de Broglie’s wave arises most naturally from this. It could possible be the mechanism of mass creation, but of gravitation as well. Questions of Lorentz symmetry, gravyphoton mass and “relativity limits” are considered in detail. The whole concept leads to change from 20th century field-geometry paradigm towards real wave-dynamic description of Universe.
The Electromagnetic Signature of Gravitational Wave Interaction with the Quantum Vacuum
An analysis of the effects of the passage of a gravitational wave on the quantum vacuum is made within the context of the Nexus paradigm of quantum gravity. Results indicate that if the quantum vacuum includes electrically charged virtual particle fields, then a gravitational wave will induce vacuum polarization.The equations of General Relativity are then reformulated to include electric charge displacements in the quantum vacuum imposed by an anisotropic stress-momentum tensor. It is then demonstrated that as a result of the space-time piezoelectric effect, a gravitational wave is associated with a rotating electromagnetic wave and that the converse effect produced by strong electromagnetic fields is responsible for the generation of relativistic jets and gamma ray bursts.Objects with strong electromagnetic fields will apparently violate the strong equivalence principle.
International Letters of Chemistry, Physics and Astronomy, 2013
In the paper, the outline of a new quantum theory of gravitation is presented. The energetic states of a material body, stable and unstable, are described. Characteristics of a body motion in a gravitation-inertia space-time has been given. It has been proved that all the time both gravitation and inertia are co-existent, independent on the position of a moving object. This is the reason of that twolink name of the space-time. A thorough in-depth analysis of the problem made it possible to state that so called the law of common gravity is a hyperbolic approximation of a proper course of inertia force. Therefore the mentioned courses have only two common points. One of them, the initial point belongs also to the course line of the gravity force, constant on the whole length of space-time. This theory is adequate in character and thus generally does not corresponds with the existent classical theory of gravitation.
Journal of Modern Physics, 2021
Quantum gravitational theory, based on the hypothesis of the absolute reference system, reveals the function of the effects of the gravitational field at the microscopic and macroscopic scale. The quantum nature of gravitational potential, and the dynamics and kinetic energy of photons and elementary particles under the influence of the gravitational field are studied, and a quantum interpretation of gravitational redshift is given. There is also a complete agreement of this quantum gravitational theory with the existing experimental data.