Deep Thinking on Capacitive and Inductive Coupling in Electrical Circuits Part 4
Internal Circular Motion and the Origin of Spin
In a previous discussion, we considered how the motion of a particle might naturally trace a circular or helical path—not necessarily in ordinary space, but in an internal or higher-dimensional field configuration space. This arises from the idea that particle motion, when constrained by field synchronization or time-delay mechanisms (as in the Tugboat Theory), would tend to follow curved trajectories due to feedback and propagation delays in the surrounding field structure.
This opens a conceptual path toward understanding the phenomenon of spin—not just as an abstract quantum number, but as an emergent property of these internal circular dynamics:
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Quantum spin is treated in standard quantum mechanics as intrinsic angular momentum, but it lacks a classical analogue. Yet, if particles are seen as phase-stable structures within fields, then internal circulation of those field structures may naturally account for what we interpret as spin.
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This interpretation aligns with known theoretical ideas like zitterbewegung, the rapid trembling motion predicted by the Dirac equation, which suggests an internal circular motion of the electron.
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The electron’s magnetic moment also implies an effective circulating current — consistent with the idea that spin is not abstract, but results from structured internal motion.
From a field synchronization standpoint:
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Spin could emerge from the circular propagation of a particle’s field configuration through a delayed, memory-laden vacuum field.
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The characteristic 720-degree symmetry of fermions could be a natural result of this looping motion through phase space — a topological feature of synchronization in nested fields.
Thus, spin may be best understood as a dynamical result of curved phase trajectories through a synchronized field landscape, rather than an innate quality.
This deepens the overall picture of coupling, fields, and motion — suggesting that even so-called intrinsic properties like spin may be emergent, grounded in how particles interact with their own field environment.
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