Particles, Fields, and the Measurement of Electron Spin
- URL: http://arxiv.org/abs/2007.00619v2
- Date: Thu, 3 Sep 2020 17:32:56 GMT
- Title: Particles, Fields, and the Measurement of Electron Spin
- Authors: Charles T. Sebens
- Abstract summary: This article compares treatments of the Stern-Gerlach experiment across different physical theories.
It builds up a novel analysis of electron spin measurement in the context of classical Dirac field theory.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: This article compares treatments of the Stern-Gerlach experiment across
different physical theories, building up to a novel analysis of electron spin
measurement in the context of classical Dirac field theory. Modeling the
electron as a classical rigid body or point particle, we can explain why the
entire electron is always found at just one location on the detector
(uniqueness) but we cannot explain why there are only two locations where the
electron is ever found (discreteness). Using non-relativistic or relativistic
quantum mechanics, we can explain both uniqueness and discreteness. Moving to
more fundamental physics, both features can be explained within a quantum
theory of the Dirac field. In a classical theory of the Dirac field, the
rotating charge of the electron can split into two pieces that each hit the
detector at a different location. In this classical context, we can explain a
feature of electron spin that is often described as distinctively quantum
(discreteness) but we cannot explain another feature that could be explained
within any of the other theories (uniqueness).
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