What question did this study set out to answer?

The research aims to establish a connection between Möbius iterations and residue geometry in holonomy.

April 15, 2026Open Access

Residue Holonomy and Prime Duality

Key Points

The research aims to establish a connection between Möbius iterations and residue geometry in holonomy.
Developed a geometric framework utilizing Möbius iterations.
Analyzed holonomy growth in a constant-defect regime.
Derived a closed-form description for the connection behavior.
Examined how residue cancellation impacts holonomy.
Identified trivial holonomy with residue cancellation indicating composite behavior.
Discovered persistent defects linked to non-cancellation demonstrating prime-like behavior.
Observed logarithmic thinning in primitive loop density parallel to the prime number theorem.

Abstract

We introduce a geometric framework in which Möbius iterations generate a meromorphic su (2) su (2) su (2) -valued connection whose holonomy is governed by a signed residue sum. Within this model, cancellation of residues produces trivial holonomy (composite-like behavior), while non-cancellation yields persistent defects (prime-like behavior). We analyze the associated dynamical system, derive a closed-form description of holonomy growth in the constant-defect regime, and show that primitive loop density exhibits logarithmic thinning analogous to the prime number theorem. The framework provides a unified perspective linking Möbius dynamics, residue geometry, and loop proliferation, while leaving the direct arithmetic correspondence as an open problem.

Residue Holonomy and Prime Duality

Key Points

Abstract

Cite This Study