Algebraic Structures of the Grothendieck-Teichmüller Group, the Cosmic Galois Group, and Associated Stability Conditions

We examine the algebraic structures governing the consistency of braided tensor categories and their realization in arithmetic geometry. We provide symbolic derivations of the Pentagon and Hexagon coherence identities. The Knizhnik-Zamolodchikov (KZ) equations are derived using the Sugawara construction and Ward identities. The flatness of the KZ connection is derived via the classical Yang-Baxter equations, and the KZ associator is constructed from asymptotic solutions. We establish that this associator satisfies the coherence identities. The Grothendieck-Teichmüller group (̂GT ) is defined via its relations on ˆF2. The action of the absolute Galois group Gal(Q/Q) on the étale fundamental group of P1 \{0, 1, ∞} is shown to satisfy thê GT relations, proving the canonical embedding Gal(Q/Q) ↪→̂GT . We demonstrate that̂ GT -compatibility imposes a genus-zero constraint, realized by the j-invariant and the Monster group (M). The theory of Complex Multiplication (CM) is detailed, proving the Main Theorem of CM. We define the Cosmic Galois Group (GCosmic) using Tannakian formalism over Spec(F1). The isomorphism GCosmic ∼=̂ GT is proven by constructing mutually inverse homomorphisms derived from their respective actions on the tower of moduli spaces and the category of absolute motives. This leads to the Adelic-Modular Isomorphism. In Noncommutative Geometry (NCG), we derive the Archimedean Shadow Identity via Mellin transforms and Plancherel measures. Geometric stability is analyzed via the L1-Poincaré-Wirtinger inequality, establishing the Variational-Modular-Arithmetic equivalence.