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Definition of Magneton: The magnetic dipole field of a stationary electron.
Definition of the term "Quantum": Not used in this research to refer to Quantum Mechanics but rather to indicate the nanosized-subnanosized scale dimension.
Published Article: Real time observation of a stationary magneton
https://doi.org/10.1016/j.rinp.2019.102793
also here: https://arxiv.org/abs/1911.05735
https://drive.google.com/file/d/1_CC...ew?usp=sharing (animation of the non-relativistic stationary magneton)
Abstract: Probing the, Quantum Magnet, field (QFM) of ferromagnets with the quantum magnetic optic Ferrolens with minimum Quantum Decoherence (QDE) and macroscopically projecting the field and flux geometry of a stationary magneton. Decoherence mechanism explained responsible for transforming the Quantum Magnet to its Classical macroscopic magnetic dipole field imprint. Magneton observed as a confined dipole energy vortex.
With other words, the Ferrolens preserves and shows the Quantum Magnet field image of a macroscopic magnet which resembles the intrinsic magnetic dipole field of the electron thus a stationary magneton. Our experimental research shows the electron geometry to be a dipole vortex. ©2019 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license.
supplementary material [13] can be found here: https://tinyurl.com/y3je49tb
comment: "It is a well - known facet of quantum field theory that everything can be described in quantum mechanical terms . The complex interactions between a physical system and its surroundings ( environment ) , disrupt the quantum mechanical nature of a system and render it classical under ordinary observation . This process is known as decoherence."
Enrich Joos from Erich Joos and H. D. Zeh version of quantum decoherence (QDE) theory, states that "decoherence can not explain the measurement problem".
The premise of the research here presented is by probing the Quantum Magnet field of a macroscopic ferromanget where electrons have minimum linear relativistic motion and by circumventing the problem of decoherence (QDE), by using an observation quantum device with minimum QDE but which can display non-decohered quantum information at the macroscale, thus the ferrolens, we can obtain and observe a non-relativistic model for the stationary magneton. In a way we can say that the Ferrolens and method acts like a "giant magnification" quantum microscope.
With other words, the Ferrolens preserves and shows the Quantum Magnet field image of a macroscopic magnet which resembles the intrinsic magnetic dipole field of the electron thus a stationary magneton.
Definition of the term "Quantum": Not used in this research to refer to Quantum Mechanics but rather to indicate the nanosized-subnanosized scale dimension.
Published Article: Real time observation of a stationary magnetonhttps://doi.org/10.1016/j.rinp.2019.102793
also here: https://arxiv.org/abs/1911.05735
https://drive.google.com/file/d/1_CC...ew?usp=sharing (animation of the non-relativistic stationary magneton)
Abstract: Probing the, Quantum Magnet, field (QFM) of ferromagnets with the quantum magnetic optic Ferrolens with minimum Quantum Decoherence (QDE) and macroscopically projecting the field and flux geometry of a stationary magneton. Decoherence mechanism explained responsible for transforming the Quantum Magnet to its Classical macroscopic magnetic dipole field imprint. Magneton observed as a confined dipole energy vortex.
With other words, the Ferrolens preserves and shows the Quantum Magnet field image of a macroscopic magnet which resembles the intrinsic magnetic dipole field of the electron thus a stationary magneton. Our experimental research shows the electron geometry to be a dipole vortex. ©2019 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license.
supplementary material [13] can be found here: https://tinyurl.com/y3je49tb
comment: "It is a well - known facet of quantum field theory that everything can be described in quantum mechanical terms . The complex interactions between a physical system and its surroundings ( environment ) , disrupt the quantum mechanical nature of a system and render it classical under ordinary observation . This process is known as decoherence."
Enrich Joos from Erich Joos and H. D. Zeh version of quantum decoherence (QDE) theory, states that "decoherence can not explain the measurement problem".
The premise of the research here presented is by probing the Quantum Magnet field of a macroscopic ferromanget where electrons have minimum linear relativistic motion and by circumventing the problem of decoherence (QDE), by using an observation quantum device with minimum QDE but which can display non-decohered quantum information at the macroscale, thus the ferrolens, we can obtain and observe a non-relativistic model for the stationary magneton. In a way we can say that the Ferrolens and method acts like a "giant magnification" quantum microscope.
With other words, the Ferrolens preserves and shows the Quantum Magnet field image of a macroscopic magnet which resembles the intrinsic magnetic dipole field of the electron thus a stationary magneton.