Abstract
A new physical quantum optic nanomagnetic device and qualitative scientific tool for visualizing in real time net quantum magnetism in macroscopic matter was introduced for the first time to Academia and the general science and research community, conceptualized its operation and methodology, and analyzed its results by the author of this thesis starting back at the year 2017. Subsequently, the following years up today, extensive pioneering research without any other existing specific literature in the subject since this was something totally new, was published by the thesis author and co authors establishing the related literature for this particular new scientific tool for making visible magnetic fields. The device which its academic name was coined by the thesis author as ferrolens in the literature, besides its research applications can have many potential applications in the industry and has the unique feature apart from the other well known methods and devices like SQUID Scannin ...
A new physical quantum optic nanomagnetic device and qualitative scientific tool for visualizing in real time net quantum magnetism in macroscopic matter was introduced for the first time to Academia and the general science and research community, conceptualized its operation and methodology, and analyzed its results by the author of this thesis starting back at the year 2017. Subsequently, the following years up today, extensive pioneering research without any other existing specific literature in the subject since this was something totally new, was published by the thesis author and co authors establishing the related literature for this particular new scientific tool for making visible magnetic fields. The device which its academic name was coined by the thesis author as ferrolens in the literature, besides its research applications can have many potential applications in the industry and has the unique feature apart from the other well known methods and devices like SQUID Scanning Magnetic Microscopy and industrial magnetic field gel based viewing film, that it can display discrete magnetic lines of force of the existing field in macroscopic magnetic matter. This gives the device automatically an edge and advantage for the thorough study of magnetic field’s geometry and topology and especially the study of complex magnetic flux manifolds like these of macroscopic magnetic arrays and magnetic lattices. Furthermore and also importantly, due to the fact that it is a nanomagnetic mesoscale optic sensor it has as we show herein, very little Quantum Decoherence therefore allowing it to display the Net Quantum Magnet Field (QMF) inside condensed matter macroscopic magnets, concerning mainly the vorticity of these magnetic fields. The author herein, describes a possible physical mechanism and theory by which these experimentally novel observed net quantum vortexing magnetic fields inside ferromagnetic matter decohere to the known classical projected outside on air, macroscopic magnetic fields topology and geometry with some interesting conclusions. The ferrolens as the author shows experimentally and analyze the results, can be used for the observation of non-homogeneous magnetic fields in ferromagnets as well as homogeneous magnetic fields like for example, inside electrical solenoids or Helmholtz coils (Helmholtz coil was constructed in our Institution by the thesis author). Another, novel application and published research of the ferrolens the author presents herein, is for the real time display of dynamic (changing) magnetic fields, for example that on a high-voltage transmitting VLF (Very Low Frequency) radio antenna. Spiking the interest of the physics community specially the well known the last decade research area of synthetic magnetic monopoles, the author herein and publication co authors published research of visualizing with the ferrolens a novel macroscopic synthetic Dirac magnetic monopole field emulator by devising and constructing a novel synthetic magnetic monopole array prototype. After all these research over the last five years and experience and analysis gathered, the author of this thesis realized and came to the very important conclusion that the ferrolens quantum optics nanomagnetic sensor display of the collective magnetic behaviour and field of the unpaired electrons inside ferromagnetic matter, can be used as a Quantum Emulator (i.e. an emulator is a physical device non-algorithmic simulator of physical phenomena) to describe the magnetic field flux manifold of the single Quantum Magnet (i.e. electron at rest or else called as a stationary magneton). We used the ferrolens display of the net quantum magnetic field of ferromagnets to extrapolate a novel spin relativistic magnetic flux manifold model for a single isolated free electron at rest with no translational motion. Please notice, our proposed electron intrinsic fiber model is semi-classical and does no need to comply with quantum mechanics type of restrictions like the Heisenberg Uncertainty Principle. It does not examine the interaction of the electron with its environment via its electric and magnetic interaction fields but focuses only on its isolated intrinsic charge. This is also the main theoretical elementary particle physics beyond the standard model research based on experimental observations presented in this thesis, with unforeseen implications to physics in the future.
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