RESEARCH INTERESTS

The Program of Research

• Since inertons are a substructure of the matter waves, it is interesting to show that the matter waves of individual particles overlap and form a common matter field surrounding any macroscopic object and just this field, i.e. inerton field, is responsible for the phenomenon of macroscopic gravity. I will demonstrate that just dynamic inertons induce the Newton's static gravitational potential 1/r of any macroscopic object. So inertons become real carriers of gravitational interaction in all range of the universe, from 10^-30 m, or the Planck size 10^-35 m (= the radius of a superparticle) to 10²⁶ m (= the observed radius of the universe) and therefore inertons should substitute for hypothetical gravitons of general relativity. In particular, it is planned to show that drawing inertons one can easily explain such phenomena as the motion of Mercury's perihelion, the bending of light by the sun, and other phenomena which formally have been predicted by the general theory of relativity.
  
  
• Investigate fluctuations of the inerton field that is radiated by the sun and measure the speed of inertons coming from some planets, or their satellites, and stars. This will mean the foundation of a new branch of astronomy, namely the inerton astronomy (the idea has been developed at teh participation of some colleagues, first of all O. Strokach, V. Didkovsky and L. Akimov - the head of the Observatory, Kharkiv, Ukraine).
  
  
• Based on the model of space shortly described above and considering photons and inertons as two major quasi-particles, which are excited in space, it will be interested to develop a submicroscopic theory of the diffraction phenomenon both for particles and photons, which today is limited only by the geometrical optics approximation (this activity would be shared with experimenters). The theory will also elucidate a microscopic nature of the phenomenon of dispersion of light and, moreover, it will show that just inertons - carriers of the matter waves - play the fundamental role in the diffraction/dispersion of photons. The mechanism of the diffractionless of single photons revealed by Dr. Emilio Panarella over 20 years ago will be accounted for as well.
  
  
• There is a possibility to apply to the quark construction. In particular, the theory admits one to define the quark, to analyze the reasons of lepton stability and instability of separate quarks, to solve the problem of confinement of quarks, to account for the fractional charge of quarks, etc.
  
  There are also other problems, which can be solved drawing the space net describing above and its excitations - inertons and photons: the disclosing of the mechanism of so-called Cold Fusion (first claimed by M. Fleischnmann and S. Pons in 1989); the inner reasons for the stability of atoms (why in a hydrogen atom the electron does not drop on the proton); the comprehension of why matter prevails over antimatter; the correct explanation of the appearance of superluminal velocity discovered recently by different experimental team;, the application to astrophysics and generalized mathematical theories describing the behavior of quantum systems at ultra small scales, which have successfully been developing by Prof. Ruggero Maria Santilli and collaborators, and so on.