Dynamical Non-Commutative Algebraic Geometry: Inflation, Bifurcation, and the Dynamics of Collapse across Division Algebras

Abstract

We develop a framework for dynamical non-commutative algebraic geometry (DNCAG) by analyzing the evolution and stability of polynomial root manifolds in real normed division algebras (H and O). We establish a Generalized Inflation Theorem, demonstrating that for central polynomials, the root set forms a homogeneous space G/H, where G is the automorphism group of the algebra (SO(3) for H, G2 for O). This mechanism generates continuous geometry from non-commutativity. We analyze the dynamics under central modulation (breathing modes), classifying topological bifurcations (=0). We then analyze the topological collapse induced by non-central perturbations, governed by symmetry reduction. We utilize the Localization Theorem (Gordon-Motzkin) to explain the alignment of roots with coefficient subalgebras. We formalize the dynamics of collapse using gradient flow on the potential landscape V(x) = \|P(x)\|2, characterizing it as a deformation retract and proving that the collapse timescale exhibits critical slowing down with quadratic scaling (T collapse ε-2). Finally, we introduce a thermodynamic formalism, proving an Entropy Scaling Law that rigorously characterizes the collapse as a symmetry-breaking phase transition.

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