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Abstrakty
In this paper an ansatz that the anti-commutation rules hold only as integrated average over time intervals and not at every instant giving rise to a time-discrete form of Klein-Gordon equation is examined. This coarse-grained validation of the anti-commutation rules enables us to show that the relativistic energy-momentum relation holds only over discrete time intervals, fitting well with the timeenergy uncertainty relation. When this time-discrete scheme is applied to four vector notations in relativity, the line-element can be quantized and thereby how the physical attributes associated with time, space and matter can be quantized is sketched. This potentially enables us to discuss the Zeno’s arrow paradox within the classical limit. As the solutions of the Dirac equation can be used to construct solutions to the Klein-Gordon equation, this temporal quantization rule is applied to the Dirac equation and the solutions associated with the Dirac equation under such conditions are interpreted. Finally, the general relativistic effects are introduced to a line-element associated with a particle in relativistic motion and a time quantized line-element associated with gravity is obtained.
Rocznik
Tom
Strony
68--86
Opis fizyczny
Bibliogr. 22 poz., wz.
Twórcy
autor
- Department of Physics, University of Colombo, Colombo3, Sri Lanka
- Department of Physics, University of Colombo, Colombo3, Sri Lanka
Bibliografia
- [1] R. Lévi, Journal de Physique et le Radium 8 (4) (1927) 182–198.
- [2] H. Snyder, Phys. Rev. 71 (1947) 38–41.
- [3] C.N. Yang, Phys. Rev. 72 (1947) 874.
- [4] H. Margenau, The Nature of Physical Reality. (McGraw-Hill, 1950).
- [3] P. Caldirola, Lett. Nuovo Cim. 27 (1980) 225–228.
- [4] S. Vaknin, Time Asymmetry Revisited (Thesis (Ph. D.), Pacific Western University (Encino, California,1982).
- [5] E.H. Suchard, J. of Modern Phys. 4 (2013) 791-806.
- [6] William G. Tifft, Astrophysical Journal 206 (1976) 38–56.
- [7] H.T Elze, Phys. Lett. A310 (2003) 110.
- [8] J.F. Barbero, Guillermo A. Mena Marugan, E.J.S Villasenor. Time uncertainty in quantum gravitational systems. arXiv:grqc/0311073, 2003.
- [9] J.J Halliwell, The Interpretation of Quantum Cosmology and the Problem of Time. arXiv:grqc/ 0208018, 2002.
- [10] Hitoshi Kitada, Quantum Mechanical Clock and Classical Relativistic Clock. arXiv:grqc/ 0102057, 2001.
- [11] N.D. George, A. P. Gentle, A. Kheyfets, W.A. Miller, The Issue of Time in Quantum Geometrodynamics arXiv:gr-qc/0302051, 2003.
- [12] B. Russell.. Our Knowledge of the External World as a Field for Scientific Method In Philosophy, (Open Court Publishing Co. 1914, Chicago)
- [13] P. Lynds. Found. of Phys. Lett. 16 (4) (2003) 343-355.
- [14] E. Schrodinger, Annalen der Physik 79 (1926) 361,489.
- [15] O. Klein, Z. Phys. 37 (1926) pp. 895–906.
- [16] W. Gordon, Z. Phys. 40 (1926–1927) pp. 117–133.
- [17] D. L. Bulathsinghala, K. A. I. L. Wijewardena Gamalath, ILCPA 9(2) (2013) 103 -115.
- [18] P. A. M. Dirac, Proc. Roy. Soc. Lond. A 117 (1928) 610-624.
- [19] Aristotle. Physics VI part 9, 239b5-7
- [18] T. Aquinas, Commentary on Aristotle’s Physics. (Dumb Ox Books, Trans. By R.J. Blackwell, R.J. Spath, W.E. Thirlkel, 1999)
- [19] H. Reichenbach. The Philosophy of Space and Time. (Dover Pub.inc. U.S.A, 1958)
- [20] L.I. Mandelshtam, I.E. Tamm Jour. phys. (USSR) 9 (1945) pp. 249–254.
- [21] P.A.M Dirac, Proc. R. Soc. Lond. A 133, (1931) 60-72.
- [22] E.C.G Stueckelberg, Helvetica Physica Acta 14 (1941) pp. 51–80.
Uwagi
Numeracja w bibliografii jest powielona [18] i [19].
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d41b5628-6d10-451f-b6e4-ba9a1994e887
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