Ari Lehto Physics Foundations Society www.physicsfoundations.org by period doubling.

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Presentation transcript:

Ari Lehto Physics Foundations Society by period doubling

We have shown earlier that several well known natural phenomena can be explained by the period doubling phenomenon in nonlinear dynamical systems assuming there are internal degrees of freedom within the systems. Each degree of freedom possesses its characteristic energy, which can be derived from the Planck energy by period doubling. The analysis shown here is based on the fusing of the 3-degree of freedom (3d) mass energy structure and 4d electromagnetic energy structure into one 3d+4d=7-degree of freedom system. Particles arrange themselves into categories, when they are ordered according to the total number of period doublings. This appears to be the same classification for the baryons and mesons as given by the Standard Model of the elementary particles but now based, instead of quarks, on natural constants (the Planck scale) and the period doubling process for each individual degree of freedom. The nucleon pair seems to be a special case and the pseudoscalar and vector mesons distinguish from the rest of the mesons. Presentation at Physics Foundations Society Seminar, August 5, 20152

The Standard Model (SM) of particles classifies particles according to their observed behavior in collision and decay processes. The classification can be explained by the hypothetical internal constituents of particles called quarks. Particles containing two quarks are called mesons, and those containing three quarks are called baryons respectively. Both together form the so called hadrons. Quark model does not apply to the leptons. A drawback of SM is that the physical properties of particles cannot be calculated, e.g. electron and proton rest energies, magnetic moments and the value of the elementary electric charge 1. We have found earlier that the mass-energy system seems to have three internal degrees of freedom (3d) and electromagnetic (EM) system four (4d). The electron and proton rest energies can be calculated from [Lehto 2009, 2014] where ’d’ means an internal degree of freedom. The rot-vib states are represented by the powers of pi. N is the total number of period doublings in the 3d system and M in the 4d system. a and b are integers, -3≤a≤3, -4≤b≤4. E oo ( MeV) is the generalized Planck energy containing both the Planck mass-energy and Planck charge Coulomb energy. Presentation at Physics Foundations Society Seminar, August 5, d (mass-energy) 4d (EM-energy) (1) 1 These values can be calculated from the Planck scale by period doubling.

Our new interpretation of (1) is that there are three independent phase-spaces, namely: 1. combined periodic space with 3+4=7 degrees of freedom, observed as 2 N/7 2. 3d rot-vib space observed as  a/3 (mass-energy system) 3. 4d rot-vib space observed as  b/4 (EM-energy system) The roots are required to return the phase-space volume to the (perceived) scalar values [Lehto 2009, 2014]. Equation (1) can now be written in the form N is the total number of period doublings (or energy halvings) and (a,b) the rot-vib mode as before. Presentation at Physics Foundations Society Seminar, August 5, (2) Product of independent phase- space volumes returned to the product of corresponding scalar values.

The total number N of period doublings can be calculated from (2), if the particle rest energy E N is known: n =a/3+b/4 in (3) is the combined power of pi in (2). Different modes (a,b) yield different N-values, and the analysis is carried out by calculating N- values for all different modes from n =-2 (a=-3, b=-4) to n =+2 (a=3, b=4) for each particle. Integer N’s are colored and written in a column in ascending order. The following tables show the results of the particle rest energy analyses using (3). Particle rest energies are taken from Particle Data Group 2014 particle listings. Presentation at Physics Foundations Society Seminar, August 5, (3) ( a,b ) n all periods, integer N chosen Partial table

6 Particles group according to the Standard Model classification K.A. Olive et al. (Particle Data Group), Chin. Phys. C38, (2014) Nucleons at (0,0)

7 Particles group according to the Standard Model classification Vector and pseudoscalar mesons separate. K.A. Olive et al. (Particle Data Group), Chin. Phys. C38, (2014)

General Period doubling in nonlinear dynamical systems means that in addition to the fundamental period  , periods 2  , 4  , 8  , 16  , 32   etc. are generated within the system. If the system has internal degrees freedom (or dimensions), then each one undergoes the doubling process independently. Rotational and vibrational states can be distinguished by a factor of pi (circumference to diameter and vice versa). Equation (2) is the new version of (1), where the 3d and 4d parts are self-contained entities. Equation (1) is found to apply to the electron and proton properties 1, Hydrogen 21 cm wavelength, 3K microwave radiation and the quantized galaxy redshifts. The Solar system seems to be a pure 3d mass system with quantized orbits and orbital velocities. Equation (2) combines the periodic parts into a single 3d+4d=7d system modified by the rot-vib states of the particles, and seems to apply to the artificial elementary particles. Note that the Planck energy reference connects the particles directly to the natural constants in both (1) and (2). The total number N of doublings must be an integer, because period doubling is exact. The rest energy of a particle determines the values for both N and the mode (a,b). Therefore ordered N’s do not yield ordered energies. Only for (0,0) particles the two orders would be the same (N alone determines the rest energy). Presentation at Physics Foundations Society Seminar, August 5, accurate values for the mass, magnetic moment and charge from the Planck scale.

It is found that particles form groups according to the classification of the Standard Model. The nucleons seem to have the fundamental structure, where the mode is (0,0). Pseudoscalar and vector mesons separate from the rest of the mesons. This means that the period doubling process is evidently connected to the true internal properties of the particles. It should be noted that period doubling is exact, therefore there is no room for adjustments or free parameters. Presentation at Physics Foundations Society Seminar, August 5, Discovery Period doubling gives birth to a period-based classification of the elementary particles. The rest energy of a particle is determined by both the total number of period doublings and the rot-vib state of the 3d mass-energy and 4d EM-energy structures.

Lehto A., ”On the Planck Scale and Properties of Matter”, Nonlinear Dynamics, 55, 3, , 2009 Lehto A., “On the Planck Scale and Properties of Matter”, International Journal of Astrophysics and Space Science, Vol. 2, Issue Number 6-1, December 2014 Presentation at Physics Foundations Society Seminar, August 5,

11 integer Random numbers, range For comparison: the baryons

12Presentation at Physics Foundations Society Seminar, August 5, 2015