Recursive quantum gauge theory
David Ritz Finkelstein
TL;DR
This paper introduces a recursive quantum gauge theory framework that models fundamental physics features through iterative Fermi-Dirac quantification, connecting gauge structure, spacetime, and the Higgs field.
Contribution
It presents a novel recursive quantum gauge theory approach with six iterations, unifying key physical concepts in a finite-dimensional setting.
Findings
Models gauge structure, spin-statistics, and spacetime metric.
Six iterations suffice to replicate present physics.
Provides a new perspective on quantum assembly of nature.
Abstract
Quantum gauge theories with finite-dimensional representation spaces are constructed that can have canonical gauge field theories as singular limits. They describe nature as a recursive quantum assembly by iterating Fermi-Dirac quantification. Six iterations are necessary and sufficient for present physics. The gauge structure, the spin-statistics correlation, the space-time metric, and the Higgs field are modeled.
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Taxonomy
TopicsQuantum Mechanics and Applications · Noncommutative and Quantum Gravity Theories · Advanced Operator Algebra Research