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Dr. Volodymyr V. Krasnoholovets
local time: 2024-03-28 09:09 (-04:00 DST)
Dr. Volodymyr V. Krasnoholovets (Abstracts)
Titles Abstracts Details
  • Variation in mass of entities in condensed media (2010) [Updated 1 decade ago]
    by Volodymyr V. Krasnoholovets   read the paper:

    The present paper further develops some previous results associated with the variation in mass of a system

    starting from first sub microscopic principles and the constitution of real space. The wave function ψ

    determined in a phase space is treated as an image of the original field of inertia determined in the real space,

    which is generated by the moving particle. Carriers of this field, inertons, are responsible for the exchange of

    mass between the substance's entities (atoms or molecules that move or vibrate in the substance). The

    overlapping of inerton clouds results in the emission and re-absorption of inertons by vibrating entities. Thus the

    mass of atoms in a substance is not a stationary parameter, but dynamic. Methods of submicroscopic mechanics

    allow a detailed study of a mass dynamics in the substance in question. Moreover, the inerton field can be

    excited in a substance and can affect other substances inducing new effects, such as ?freezing? and clusterization

    of entities, which can give rise to new chemicals. Besides, those are inertons that synchronize the coherent

    motion of ultracool atoms bringing them to the cluster state, which is identified with the phenomenon of

    Bose-Einstein condensation.


  • Sub microscopic description of the diffraction phenomenon (2010) [Updated 1 decade ago]
    by Volodymyr V. Krasnoholovets   read the paper:

    It is shown that a detailed sub microscopic consideration denies the waveparticle

    duality for both material particles and field particles, such as

    photons. In the case of particles, their ψ-wave function is interpreted as the

    particle?s field of inertia and hence this field is characterised by its own field

    carriers, inertons. Inertons and photons are considered as quasi-particles,

    excitations of the real space constructed in the form of a tessel-lattice. The

    diffraction of photons is explained as the deflection of photons from their

    path owing to transverse flows of inertons, which appear in the substance

    under consideration at the decay of non-equilibrium phonons produced by

    transient photons.


  • Sub Microscopic Description of the Diffraction Phenomenon (2010) [Updated 1 decade ago]

    It is shown that a detailed sub microscopic consideration denies the waveparticle duality for both material particles and field particles, such as photons. In the case of particles, their ψ-wave function is interpreted as the particle's field of inertia and hence this field is characterized by its own field carriers, inertons. Inertons and photons are considered as quasi-particles, excitations of the real space constructed in the form of a tessel-lattice. The diffraction of photons is explained as the deflection of photons from their path owing to transverse flows of inertons, which appear in the substance under consideration at the decay of non-equilibrium phonons produced by transient photons.


  • On Microscopic Interpretation of Phenomena Predicted by the Formalism of General Relativity (2009) [Updated 7 years ago]

  • On Microscopic Interpretation of the Phenomena Predicted by the Formalism of General Relativity (2008) [Updated 1 decade ago]
    by Volodymyr V. Krasnoholovets   read the paper:

    The main macroscopic phenomena predicted by general relativity (the motion of Mercury's perihelion, the bending of light in the vicinity of the sun, and the gravitational red shift of spectral lines) are studied in the framework of the sub microscopic concept that has recently been developed by the author. The concept is based on the dynamic inerton field that is induced by an object in the surrounding space considered as a tessellation lattice of primary balls (superparticles) of Nature. Submicroscopic mechanics says that the gravitational interaction between objects must consist of two terms:

    1. the radial inerton interaction between two masses M and m, which results in classical Newton's gravitational law U = - GMm/r
    2. the tangential inerton interaction between the masses, which is caused by the tangential component of the motion of the test mass m and which is characterized by the correction - G(Mm/r)(v2/c2).

    It is shown it is precisely this correction that is responsible for the three aforementioned macroscopic phenomena and the derived equations exactly coincide with those derived in the framework of the formalism of general relativity, which means that the latter must be reinterpreted as follow: the gravitational field of the resting central mass is flat, but the emergence of a test mass disturbs the field and its distribution exactly looks like the Schwarzschild metric prescribes.


  • Reasons for Gravitational Mass and the Problem of Quantum Gravity (2006) [Updated 7 years ago]

    The problem of quantum gravity is treated from a radically new viewpoint based on a detailed mathematical analysis of what the constitution of physical space is, which has been curried out by Michel Bounias and the author. The approach allows the introduction of the notion of mass as a local deformation of space regarded as a tessellation lattice of founding elements, topological balls, whose size is estimated as the Planck one. The interaction of a moving particle-like deformation with the surrounding lattice of space involves a fractal decomposition process that supports the existence and properties of previously postulated inerton clouds as associated to particles. The cloud of inertons surrounding the particle spreads out to a range ??/c=? from the particle where ? and c are velocities of the particle and light, respectively, and ? is the de Broglie wavelength of the particle. Thus the particle's inertons return the real sense to the wave ?-function as the field of inertia of the moving particle. Since inertons transfer fragments of the particle mass, they play also the role of carriers of gravitational properties of the particle. The submicroscopic concept has been verified experimentally, though so far in microscopic and intermediate ranges.


  • The Tessellattice of Mother-Space as a Source and Generator of Matter and Physical Laws (2006) [Updated 1 decade ago]