Quantization in relativistic classical mechanics:
the Stueckelberg equation, neutrino oscillation and large-scale structure of the universe
Department of Theoretical and Experimental Nuclear Physics,
Odessa National Polytechnic University, 65044 Odessa, Ukraine
Based on the Chetaev theorem on stable dynamical trajectories in the presence of dissipative forces [1], we obtain the generalized condition for stability of relativistic classical Hamiltonian systems (with an invariant evolution parameter) in the form of the Stueckelberg equation. As is known, this equation is the basis of a competing paradigm known as parametrized relativistic quantum mechanics (pRQM). It is shown that the energy of dissipative forces, which generate the Chetaev generalized condition of stability, coincides exactly with Bohmian relativistic quantum potential. Within the framework of Bohmian RQM supplemented by the generalized Chetaev theorem and on the basis of the principle of least action for dissipative forces, we show that the squared amplitude of a wave function in the Stueckelberg equation is equivalent to the probability density function for the number of particle trajectories, relative to which the velocity and the position of the particle are not hidden parameters.
The conditions for reasonableness of trajectory interpretation of pRQM are discussed. On basis of analysis of a general formalism for vacuum-flavor mixing of neutrino within the context of the standard and pRQM models we show that the corresponding expressions for the probability of transition from one neutrino flavor to another differ appreciably, but they are experimentally testable: the estimations of absolute value for neutrino mass based on modern experimental data for solar and atmospheric neutrinos show that the pRQM results have a preference. It is noted that the selection criterion of mass solutions relies on proximity between the average size of condensed neutrino clouds, which is described by the Muraki formula (29th ICRC, 2005) and depends on the neutrino mass, and the average size of typical observed void structure (dark matter + hydrogen gas), which plays the role of characteristic dimension of large-scale structure of the Universe.
[1] Rusov V.D. et al., Quantization in classical mechanics and its relation to the Bohmian Psi-field, Ann. of Physics 326 (2011) 1807-1815.
Personal Information:
Born in Odessa (Ukraine), November 06, 1949.
Moscow Engineering Physics Institute, 1978.
Ph.D. Moscow Engineering Physics Institute, 1983.
D. Sci Moscow Engineering Physics Institute, 1992.
Professor of Nuclear Physics, since 1998.
Married; two children.
Current affiliation: Head of Department of Theoretical and Experimental Nuclear Physics,
Odessa National Polytechnic University, 1997-present.
Fields: Nuclear physics, High Energy Physics, Quantum Foundations, Astroparticle physics,
Neutrino physics, Stochastic nuclear dynamics, Reactor physics, Physics of climate,
Soft Radiation physics.
More than 100 publications including 4 monographs.