Abstract
The microlocal space of hadronic matter extension has recently been characterized as a Finsler space. This consideration of hadrons extended as composites of constituents can give rise to a dynamical theory of hadrons. The macrospaces, the space-time of common experience (the Minkowski flat space-time) and the Robertson-Walker background space-time of the universe, are found to appear as the “averaged” space-times of the Finsler space that describes the anisotropic nature of the microdomain of hadrons. From the assumed property of the fields of the constituents in the microspace it is possible to find the field (or wave) equations of the particles (or constituents) through the quantization of space-time at small distances (to an order of or less than a fundamental length). If the field (or wave) function is separable in the functions of the coordinates of the underlying manifold and the directional arguments of the Finsler space, then the former part of the field function is found to satisfy the Dirac equation in the Minkowski space-time or in the Robertson-Walker space-time according to the nature of the underlying manifold. In the course of finding a solution for the other part of the field function a relation between the mass of the particle and a parameter in the metric of the space-time has been obtained as a byproduct. This mass relation has cosmological implications and is relevant in the very early stage of the evolution of the universe. In fact, it has been shown elsewhere that the universe might have originated from a nonsingular origin with entropy and matter creations that can account for the observed photon-to-baryon ratio and total particle number of the present universe. The equations in the directional arguments for the constituents in the hadron configuration are found here and give rise to an additional quantum number in the form of an “internal” helicity that can generate the internal symmetry of hadron if one incorporates the arguments of Budini in generating the internal isospin algebra from the conformal reflection group. This consideration can also account for the meson-baryon mass differences.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Antonelli, P. L., Ingarden, R. S., and Matsumoto, M. (1993).The Theory of Sprays and Finsler Spaces with Applications in Physics and Biology, Kluwer, Dordrecht, Holland.
Asanov, G. S. (1985).Finsler Geometry, Relativity and Gauge Theories, Reidel, Dordrecht, Holland.
Asanov, G. S., and Kiselev, M. V. (1988).Reports on Mathematical Physics,26, 401.
Asanov, G. S., Ponomorenko, S. P., and Roy, S. (1988),Fortschritte der Physik,36, 697.
Bandyopadhyay, P. (1984).Hadronic Journal,7, 1706.
Bandyopadhyay, P. (1989).International Journal of Modern Physics A,4, 4449–4467.
Bandyopadhyay, P., and Ghosh, P. (1989).International Journal of Modern Physics A,4, 3791–3805.
Beil, R. G. (1989).International Journal of Theoretical Physics,28, 659–667.
Beil, R. G. (1992).Internatioanl Journal of Theoretical Physics,31, 1025–1044.
Berwald, L. (1941).Mathematica (Timisoara),17, 34.
Blokhintsev, D. I. (1978). Preprint of the Joint Institute for Nuclear Research, Dubna, no. E2-11297.
Budini, P. (1979).Nuovo Cimento,53A, 31.
Cartan, E. (1934).Les Espaces de Finsler, Hermann, Paris.
Cartan, E. (1966).The Theory of Spinors, Hermann, Paris.
De, S. S. (1986a).International Journal of Theoretical Physics,25, 1125.
De, S. S. (1986b).Hadronic Journal Supplement,2, 412.
De, S. S. (1989). InHadronic Mechanics and Nonpotential Interaction, M. Mijatovic, ed., Nova Science Publishers, New York, p. 37.
De, S. S. (1991). In Hadronic Mechanics and Nonpotential Interaction-5, Part II, Physics, H. C. Myung, ed., Nova, New York, p. 177.
De, S. S. (1993a).International Journal of Theoretical Physics,32, 1603.
De, S. S. (1993b).Communications in Theoretical Physics,2, 249.
De, S. S. (1995).Communications in Theoretical Physics,4, 115.
Finsler, P. (1918). Über Kurven und Flächen in Allgemeinen Räumen, Dissertation, University of Göttingen.
Matsumoto, M. (1986).Foundation of Finsler Geometry and Special Finsler Spaces, Kaiseisha Press, Shigaken, Japan.
Namsrai, Kh. (1985)International Journal of Theoretical Physics,24, 741–773, and references therein.
Perl, M. L. (1974).High Energy Hadron Physics, Wiley, New York.
Prigogine, I. (1989).International Journal of Theoretical Physics,28, 927.
Riemann, G. F. B. (1854). Uber die Hypothesen welche der Geometrie zu Grunde liegen, Habilitation thesis, University of Göttingen.
Rund, H. (1959).The Differential Geometry of Finsler Spaces, Springer-Verlag, Berlin.
Weinberg, S. (1989).Review of Modern Physics,61, 1, and references therein.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
De, S.S. Internal symmetry of hadrons: Finsler geometrical origin. Int J Theor Phys 36, 89–110 (1997). https://doi.org/10.1007/BF02435773
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF02435773