Entangled Electron for New Quantum Mechanics Part 1

This work advances the theoretical framework of the electron model introduced in a previous paper (viXra: 2411.0050 -Quantum Physics) , which describes the electron as composed of entangled mass elements . This model proposes an extension of the de Broglie-Bohm (dBB) paradigm , achieving compatibility with Special Relativity . Explicit expressions for 𝑍 and 𝑍𝐶 are derived , describing the sequence of orbitals and their associated masses , along with a detailed analysis of their physical significance . An innovative interpretation of spin and magnetic moment is presented , viewing them as invariant properties across orbitals , despite variations in the associated parameters . This perspective provides a potential explanation for the experimentally observed phenomenon of spatial spin separation from its particle . Additionally , the Appendix includes applications of the 𝑀𝑍 matrix—a conceptual tool integral to the proposed formalism—for estimating particle masses, specifically those of the muon and tauon, with notable accuracy. This work represents the second part of a trilogy. A forthcoming extension will focus on the characteristics of orbitals, with particular emphasis on the definition of attractive and repulsive potentials and the associated Hamiltonian, thereby completing the theoretical framework.