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Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
by Guan, Zhong
in Anti-parallel Magnetic Moment / Electron spin / Electrons / Entangled states / Fluxon / Magnetic circuits / Magnetic fields / Magnetic flux / Magnetic induction / Magnetic moments / Magnetism / Maximally Entangled State / Maximum Possible Magnetic Induction / Physics / Quantization of Magnetic Moment Direction / Qubit experiment
2022
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Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
by Guan, Zhong
in Anti-parallel Magnetic Moment / Electron spin / Electrons / Entangled states / Fluxon / Magnetic circuits / Magnetic fields / Magnetic flux / Magnetic induction / Magnetic moments / Magnetism / Maximally Entangled State / Maximum Possible Magnetic Induction / Physics / Quantization of Magnetic Moment Direction / Qubit experiment
2022
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Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
by Guan, Zhong
in Anti-parallel Magnetic Moment / Electron spin / Electrons / Entangled states / Fluxon / Magnetic circuits / Magnetic fields / Magnetic flux / Magnetic induction / Magnetic moments / Magnetism / Maximally Entangled State / Maximum Possible Magnetic Induction / Physics / Quantization of Magnetic Moment Direction / Qubit experiment
2022

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Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?
Journal Article

Two Entangled Electrons How to Link to Each Other?—What’s the Magnetic Force State on Both Sides?

Guan, Zhong
2022
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Overview
There discovered the maximum possible magnetic induction in nature, equal to the magnetic induction at the poles of an electron’s spin, When the spin magnetic moments of two electrons are close to each other, they act on each other with the maximum possible magnetic induction, and finally entered the maximally entangled state after the energy drops. By this time, the spin magnetic moments on both sides situated in anti-parallel, between them there existed four invisible magnetic circuit, and each magnetic circuit just contain a fluxon. No matter how far the distance between the spins, owing to the inalienability of fluxon, no magnetic flux leakage (coupling degree 100%), so these four magnetic circuit will always existed, maintaining the maximally entangled state system immutably. This is the material basis for the entangled state to be existed, nothing to do with “spooky action at a distance”. In this paper, a visual schematic diagram has drawn to describe these, and the magnetic force state, force relationship and “light barrier” problem are analyzed.
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Publisher
IOP Publishing
Subject

Anti-parallel Magnetic Moment

/ Electron spin

/ Electrons

/ Entangled states

/ Fluxon

/ Magnetic circuits

/ Magnetic fields

/ Magnetic flux

/ Magnetic induction

/ Magnetic moments

/ Magnetism

/ Maximally Entangled State

/ Maximum Possible Magnetic Induction

/ Physics

/ Quantization of Magnetic Moment Direction

/ Qubit experiment

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