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Rotational Invariance and the Spin-Statistics Theorem
Foundations of Physics 33 (9):1349-1368 (2003)
Abstract
In this article, the rotational invariance of entangled quantum states is investigated as a possible cause of the Pauli exclusion principle. First, it is shown that a certain class of rotationally invariant states can only occur in pairs. This is referred to as the coupling principle. This in turn suggests a natural classification of quantum systems into those containing coupled states and those that do not. Surprisingly, it would seem that Fermi–Dirac statistics follows as a consequence of this coupling while the Bose–Einstein follows by breaking it. In Sec. 5, the above approach is related to Pauli's original spin-statistics theorem and finally in the last two sections, a theoretical justification, based on Clebsch–Gordan coefficients and the experimental evidence respectively, is presentedLinks
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Citations of this work
Quantum Mechanics and the Metrics of General Relativity.Paul O’Hara - 2005 - Foundations of Physics 35 (9):1563-1584.
Quantum particles as conceptual entities: A possible explanatory framework for quantum theory. [REVIEW]Diederik Aerts - 2009 - Foundations of Science 14 (4):361-411.
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