Vo Van Thuan Vietnam-Auger Cosmic Ray Laboratory

1. International Conference on Particle Physics Astrophysics and Quantum Field TheoryShowing-up the Extra-Dimensions of Electron Vo Van Thuan Vietnam-Auger Cosmic Ray Laboratory Institute of Nuclear Science and Technology (INST)179 Hoang Quoc Viet Street, Nghiado, Hanoi, VietnamE-mail: vvthuan@vaec.gov.vn Singapore, 27th-29th November 2008

2. Contents • Introduction. • Equation of a free spinning micro-particle. • Equation of a free electron. • Semi-classical interpretation of quantum mechanics. • Conclusions. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

3. I. Introduction (1) • For the early time the extra-dimensions (EDs) have been proposed by Kaluza-1921 and Klein-1926 [1,2] in their theory where the 5th space axis being adopted as a realistic one, but is to be compacted in a tiny cylinder then should be hidden from observation . • Klein and Fock-1926 [2,3] were the first to show a technique that the equation of motion of a massive particle in 4D time-space is able to obtained by reducing the ED of a massless wave equation in a higher dimensional time-space. • The semi-classical approach to the equation of motion is related to the fundamental problem of hidden parameters in quantum mechanics set up by de Broglie-1927, Bohm-1952 et al. [4,5]. • Bell-1964 [6] shown the way to test the hidden parameters vs the QM. The experimental evidences of violation of the Bell inequality by Freedman-1972 et al. [7] have almost closed the models of local hidden parameters.  However, they do not ban the non-local hidden variables. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

4. I. Introduction (2) • Two trends: • The high dimensional superstring theory including the internal dynamical symmetries the EDs are internal, almost abandoned to show-up. • Theories with extra-dimensions developing in geometrical dynamics following the Kaluza-Klein formalism the EDs are of both: compacted as well as shown-up. • Two main approaches by geometrical dynamics (the 2nd trend) : - The membrane models,for example, Randall-1999[8] - The so-called induced matter models - Wesson et al. [9,10]. In particular (the induced matter models): Wesson-1992 [9] proposed a space-time-matter model regarding the proper mass as a time extra-dimension. Koch-2008 [11] proposed a geometrical model with an additional time dimension for interpretation of the Klein-Gordon equation. • Present study (for the induced-matter approach) is aiming to meet the physical reality based on: - the assumption in VVT-[12] of the space-time symmetry; - a simplification of the geometrical dynamics. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

5. II. Equation of a free spinning micro-particle (1) • Defining a symmetrical Minkowski {3T,3X} time-space we introduce a classical flat wave equation: (1) • Following Zeldovich-1968 [13] we assume, qualitatively, that the fluctuations of a physical vacuum as a global effect of the averaged cosmological constant would be a mechanism for rolling the transverse time axes. • Defining the wave (1) polarized circularly along the axis thus its evolution keeping from the past to the future is restricted by a cylindrical condition . • The polar coordinates are used for the 3D-time and the wave (1) now reads : (2) (3) defines the contribution of spin (3D gyroscope) characterizing an intrinsic transverse motion around the linear axis Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

6. II. Equation of a free spinning micro-particle (2) • The equation (2) performs a separation of variables and reduces the 6D time-space into 5D-manifold which can be reminiscent of the Kaluza-Klein theory. Putting (2) in (1) we get an equation corresponding to the real part of the equation (1): (4) As is orthogonal to then: Now the equation (4) reads: (5) (6) • Equivalent to the traditional Lorentz condition an orthogonal condition is proposed here to compensate contribution of the longitudinal terms in the parentheses of (6) as: (7) Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

7. II. Equation of a free spinning micro-particle (3) • Assuming: the invariant cylindrical condition in 3D-time (3) to produce the proper mass of the material point in 4D time-space accounting a contribution of the intrinsic spinning in 3D-space: • The unification (5) of two orthogonal time axes hides the proper time (as an independent variable) and reduces the 5D manifold into a 4D time-space : • Here is the mass-scale calibration parameter. • The equation (6) with the condition (7) is equivalent to the system of Proca’s quantum relativistic equations of massive vector boson (spin 1) • Thus, this leads to the equation describing micro-particle with a given spin: (8) (9) Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

8. III. Equation of a free electron (1) • Defining that an individual electron has a spin rotating freely in 3D-space, adopting only one of the two its projections on a given space axis, as its space-polarization. Consequently: • To get the Dirac-like equations of electron, we now apply the equation (8) containing explicitly the spin-term a long with the proper mass to implement the Dirac factorization. • Recalling that the wave function of electrons consists of four components, equivalent to a 4-spinor: or two 2-component spinors : which characterize four combinations of: i/ two polarizations in 3D-time and ii/ two opposite orientations of spin in 3D-space. • The negative time polarization with defines as an eigenstate of positron with positive additive charges and positive energy. It means the electric charge serves an indicator for the sign of time polarization. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

9. III. Equation of a free electron (2) • The system of spinor equations derived from (8) now reads: (10) • Where . The spin-term (spin ½) with a fixed polarization violates the space-parity. In the meantime, the PNC effects have been observed by polarized (neutron or neutrino) beams only in weak interaction [14,15]  thus, we simplify techniques by phenomenology  which makes the spin-term at low energies effectively proportional to the first order of Fermi constant (why this used be neglected). • Recalling that our PNC experiments-1983 [15] estimated by Sushkov & Flambaum-1982 [16] proved clearly that the PNC contribution without any special enhancement is of a factor of ~10E-7 less than the nuclear force. • When we establish the differential equation of the second order (8) from the linear equation (10), the square spin-term as an individual property should be presented there even there is no polarization in the ensemble of electrons. • As less as the square spin-term is of the order of its contribution in (8) used hardly to separate from the total rest mass. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

10. III. Equation of a free electron (3) • In a non-relativistic situation, the square differential equation (8) turns to a more general Schrödinger equation of a free electron which accounts explicitly the square spin contribution: (11) • Considering a 3D-space restricted condition of geodesic deviation, we get the relation: (12) • With the cylindrical symmetry, the Christoffel symbol  which converts the last additional term in the generalized Schrödinger equation (11) to a similar term to the so-called “quantum potential” in the Bohm theory [5]. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

11. IV. A semi-classical interpretation of quantum mechanics (1) The imaginary part of the wave equation (1) reads: (13) where the signs +/- correspond to opposite polarizations in 3D space. For individual polarized electron, the equation (13) leads to: (14) From (14) we get:(15) In according to (3) and the orthogonality of and we get: & From (15) we introduce a classical continuity equation of “a single particle”: (16) Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

12. IV. A semi-classical interpretation of quantum mechanics (2) Related to the physical reality of the individuality of micro-particles: • In according to the geometrical dynamics we are able to predict the objective properties of an individual particle. However, -Due to the non-locality of the time-like extra-dimension variables which is, in principle, varying continuously not only in the micro-objects of a given experiment but also in the measuring equipments. -Due to violent fluctuations in the interfering space-time structure of the unified object-equipment system, •  We are able to extract the physical reality almost only statistically, i.e. by averaging integrally over a coherent ensemble of micro-particles (playing the role of the objects to be measured). It is in consistency with statistical interpretation of quantum mechanics. • The situation would be better when we can measure an isolated particle or can create some coherent effects in macroscopic scale, where an ensemble of identical particles carry out the same physical information as of an individual particle. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

13. IV. A semi-classical interpretation of quantum mechanics (3) Related to the extra-dimensions: • Based on the space-time symmetry with a simplest mode of time-space structure  the 4D equations of quantum mechanics are naturally derived from the 6D classical equation of a polarized wave. • We proved that the quantum wave function and the proper time are the two transverse time-like extra-dimensions contributing to a full time-space evolution of a micro-particle. • Being not hidden, but acting explicitly in the quantum mechanics those EDs are not restricted in a hidden compacted volume, but should be shown up in an acceptable time-space scale of micro-particle (for electron, it is a distance of the Compton wave length). • Moreover, we could extract an invariant term related the micro-space structure which defines the contribution of intrinsic angular momentum (spin) to the rest mass of a micro-particle. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

14. IV. A semi-classical interpretation of quantum mechanics (4) Related to the particle-wave duality: • On one side, the given effects of reduction (2) and (3) define simultaneously, the localizing quantization of the 6D time-space evolution of a micro-particle as a material point. • On another side, they show up a non-local 4D time-space structure of the wave nature of the same micro-particle.  As a result, the proposed geometrical dynamics being in consistency with the equivalent principle of general relativity approaches to the origin of the wave-particle duality of quantum mechanics. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

15. V. Conclusions • The formalism of the Kaluza-Klein theory has been extended to the {3T,3X} symmetrical Minkowski time-space and then, • The Klein-Fock procedure has been applied to reduce a 6D time-polarized wave equation to an equation of Klein-Gordon-Fock type describing the motion of a spinning particle in 4D time-space. Such an equation being proved more general is able to lead to particular equations of scalar and vector bosons as well as of electron. • It was found that the quantum wave function and the proper time are two “transverse” time extra-dimensions contributing to a full space-time realistic evolution of a micro-particle.  They are not restricted in a hidden compacted volume, but should be shown up in an acceptable time-space scale of a nominal micro-particle. • The fundamental problems of quantum mechanics (the physical reality of an individual micro-particle, the wave-particle duality etc.) have been treated effectively by the geometrical dynamics. • In particular, it was shown that the “quantum potential” of a micro-particle, such as of an electron, originates from spinning of its non-local space-time structure. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

16. References • T. Kaluza, Sitz. Preuss. Akad. Wiss. 33(1921)966. • O. Klein, Z. f. Physik 37(1926)895. • V. Fock, Z. f. Physik 39(1926)226. • L. de Broglie, J. Phys. et Radium 8(1927)225. • D. Bohm, Phys.Rev.85(1952)166, 180. • J.S. Bell, Physics 1(1964)195. • S.J. Freedman and J.F. Clauser, Phys.Rev.Lett. 28(1972)938. • L. Randall and R. Sundrum, Phys.Rev.Lett. 83(1999)4690. • P.S. Wesson, Phys. Lett. B276(1992)299. • S.S. Seahra, P.S. Wesson, Gen.Rel.Grav. 33(2001)1731. • B. Koch, arXiv:0801.4635v1[quant-ph], 2008. • Vo Van Thuan, Vietnam Communications in Physics 9(1999)61. Vo Van Thuan, in Proc. of Osaka Forum on Frontiers of Basic Science. Hanoi, Vietnam, Sept.27-29, 2005. Ed. H. Takabe, N.H. Long and Y. Onuki. Osaka University Press, Osaka, Japan, 2006. • Ya.B. Zeldovich, Usp.Fiz.Nauk 95(1968)209. • F.J. Hasert et al., Phys.Lett. B46(1973)138. • V.P. Alfimenkov, S.B. Borzakov, Vo Van Thuan, Yu.D. Mareev, L.B. Pickelner, A.S. Khrykin, E.I. Sharapov. Nucl.Phys. A398(1983)93. • O.P. Sushkov and V.V. Flambaum, Usp.Fiz. Nauk 136(1982)2. Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008

17. Acknowledgement: I would like to thank my colleagues in the Vietnam-Auger cosmic ray laboratory (INST) for their cooperation. This research has been done under financial support of the Council of the National Program for Research in Natural Sciences, Ministry of Science and Technology of Vietnam (MOST). Thank you for your attention! Vo Van Thuan- PAQFT08, Singapore, 29 Nov. 2008