A particle model based on direct interpretation of Compton scattering measurements and gamma spectroscopy

Abstract: I present a particle model that is based on a direct interpretation of Compton scattering measurements, gamma spectroscopy, and magnetic moment data. To correctly interpret nuclear measurements, we strictly adhere to foundational Physics laws, such as the Maxwell and Klein-Nishina equations. It turns out that an electron's and a proton's internal structures can be modeled analogously; the main difference is the topology of their Zitterbewegung. This result implies that the neutron-proton difference is the additional presence of a negative elementary charge, i.e. the neutron has two sub-particles. We develop a precise mass measurement method for measuring the negative charge's mass within the neutron, and also survey relevant experiments. Numerous experiments converge to the same result: the neutron comprises a proton and a nuclear electron, whose mass is 1.554 MeV, and the binding energy of these two neutron components is 0.26 MeV. Our work clarifies that all tangible matter comprises three elementary particle types: electron, nuclear electron, and proton. We begin the discussion of unstable particles by considering magnetic moment difference between an electron and muon. Finally, we discuss what pion-related nuclear reactions reveal about the pion's internal structure. The reviewed experimental data lead to a reasonable approximation of the muon's and pion's internal structures as well. The muon turns out to be an elementary particle, the neutral pion has two sub-particles, while the charge pion has three sub-particles.

mathematical physicsgeneral physicsquantum physics

Audience: researchers in the topic

( video )

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QM Foundations & Nature of Time seminar

Series comments: Description: Physics foundations discussion seminar

Current access link in th.if.uj.edu.pl/~dudaj/QMFNoT

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