Euler’s identity, eⁱπ + 1 = 0, is universally celebrated as the epitome of mathematical beauty, yet it is strictly bound to the commutative, smooth geometry of a two-dimensional complex plane. As dimensional complexity increases, this commutative illusion collapses. This paper deconstructs the aesthetic limits of Euler’s formulation and expands its structural philosophy into the non-commutative, N dimensional realms governed by Rough Operator Algebra (ROA) and the Seonggil Torsion-Curvature Tensor (STCT). By redefining geometric anomalies—such as the self-intersection of the Klein bottle in 3D space—as algebraic residuals rather than structural failures, we introduce the Torsion-Compensated Trace and the ROA Gauss-Bonnet Theorem. Furthermore, this algebraic equilibrium is applied to the Atiyah-Singer Index Theorem via a Torsion-Compensated Dirac Operator. We demonstrate that the algebraic residual Fint interacting with the chiral operator γ5 geometrically enforces the bifurcation of fermion spin states, providing a purely geometric and algebraic proof for local Parity (P) and Time-reversal (T) symmetry violations, ultimately leading to local CPT violation in extreme quantum topological spaces.
lee seonggil (Tue,) studied this question.