dorsal/arxiv
View SchemaCharacterization of Fundamental Particles
| Authors | Ben J Baten |
|---|---|
| Categories | |
| ArXiv ID | physics/0009085 |
| URL | https://arxiv.org/abs/physics/0009085 |
| License | http://arxiv.org/licenses/nonexclusive-distrib/1.0/ |
Abstract
This report provides an alternative to the Standard Model of particle physics. The model described here is based on results from Quantum Field Mechanics, according to which all fundamental particles and interactions originate from the interaction of two pre-space/pre-time protofields. In contrast with the Standard Model, (virtual) interaction-particles are absent in the description of any of the four fundamental interactions. Electrons perform a single quantum beat process while mesons and baryons have, respectively, two and three bound quantum beat processes. Quantum Field Mechanics suggests that the charge of an electron and positron can be identified with the two possible phases of a quantum beat process as observed in the electromagnetic protofield. This report assumes that short-range binding interaction between quantum beat processes has a masking effect on the externally observable charge of hadrons. Using this assumption, the internal structure of particles is derived from their known particle charges and relative masses. The particle structures are used to obtain the so-called charge-quantum phase law. The fractional charge of quantum beat processes inside a particle is deduced by rewriting the charge-quantum phase law in terms of a linear combination of charge contributions of individual constituent quantum beat processes. Strangeness and isospin are mathematically defined in terms of the quantum beat phases of sets of particles of the same type. Application of conservation laws to particle processes leads to relations between quantum phase, strangeness and isospin.
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"abstract": "This report provides an alternative to the Standard Model of particle\nphysics. The model described here is based on results from Quantum Field\nMechanics, according to which all fundamental particles and interactions\noriginate from the interaction of two pre-space/pre-time protofields. In\ncontrast with the Standard Model, (virtual) interaction-particles are absent in\nthe description of any of the four fundamental interactions. Electrons perform\na single quantum beat process while mesons and baryons have, respectively, two\nand three bound quantum beat processes. Quantum Field Mechanics suggests that\nthe charge of an electron and positron can be identified with the two possible\nphases of a quantum beat process as observed in the electromagnetic protofield.\nThis report assumes that short-range binding interaction between quantum beat\nprocesses has a masking effect on the externally observable charge of hadrons.\nUsing this assumption, the internal structure of particles is derived from\ntheir known particle charges and relative masses. The particle structures are\nused to obtain the so-called charge-quantum phase law. The fractional charge of\nquantum beat processes inside a particle is deduced by rewriting the\ncharge-quantum phase law in terms of a linear combination of charge\ncontributions of individual constituent quantum beat processes. Strangeness and\nisospin are mathematically defined in terms of the quantum beat phases of sets\nof particles of the same type. Application of conservation laws to particle\nprocesses leads to relations between quantum phase, strangeness and isospin.",
"arxiv_id": "physics/0009085",
"authors": [
"Ben J Baten"
],
"categories": [
"physics.gen-ph"
],
"license": "http://arxiv.org/licenses/nonexclusive-distrib/1.0/",
"title": "Characterization of Fundamental Particles",
"url": "https://arxiv.org/abs/physics/0009085"
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