Ten-dimensional superstring, eleven-dimensional M-theory and F-theory suffer from inherent fundamental theoretical limitations, which essentially originate from the mathematical incompletenessmathematical incompleteness of classical complex analysis, C*-algebra and topological field theory established in the 20th century. The classical Calabi-Yau manifold and Mongé-Ampère equation proposed by Yau Shing-Tung are only valid for static commutative Kähler manifolds, lacking high-order quantum distortion correction mechanisms and incapable of characterizing noncommutative spacetime features at the Planck scale. Witten’s topological quantum field theory fails to introduce discrete number-theoretic topological constraints, resulting in persistent vacuum degeneracy, non-unique topological extremum values and the absence of global analytical zero-residual solutions. The Langlands program remains confined to abstract algebraic duality conjectures without explicit geometric dual expressions. Furthermore, long-standing difficulties including infinite moduli space degeneracy in string theory, quantum ultraviolet divergence, dimensional recursion discontinuity and empirical fitting dependence of fundamental physical constants cannot be fundamentally resolved using conventional classical mathematical tools. To address these interdisciplinary bottlenecks, this study constructs an original, fully self-consistent mathematical framework based on a self-developed 400-order global topological number theory system, completely independent of classical formula modification and empirical correctionthis study constructs an original, fully self-consistent mathematical framework based on a self-developed 400-order global topological number theory system, completely independent of classical formula modification and empirical correction. The core innovations include a series of proprietary high-order equations: the MTSP discrete-continuous structure-preserving isomorphic mapping formula, the global zero-residual high-order convergence equation system, the quantum high-order Mongé-Ampère global closed-form equation, the dimensional density topological evolution identity, the explicit Langlands-CY spectral duality formula, the global computational complexity reduction limit formula, and the prime topological scale conservation hyper-identitythe MTSP discrete-continuous structure-preserving isomorphic mapping formula, the global zero-residual high-order convergence equation system, the quantum high-order Mongé-Ampère global closed-form equation, the dimensional density topological evolution identity, the explicit Langlands-CY spectral duality formula, the global computational complexity reduction limit formula, and the prime topological scale conservation hyper-identity. This novel theoretical framework provides a rigorous mathematical foundation for solving inherent defects in classical mathematical and physical theories. Taking the 30/210 primitive modular orthogonal topological basis as the low-dimensional benchmark and infinitely nested coprime prime modulus spectra as the high-dimensional analytical carrier, this work strictly provesthe global convergence theorem of modular spectrathe global convergence theorem of modular spectra and establishes a rigorous bridge connecting discrete analytic number theory and continuous differential geometry via a newly constructed topological number theory calculus systema rigorous bridge connecting discrete analytic number theory and continuous differential geometry via a newly constructed topological number theory calculus system. Three core self-developed mathematical tools, namely the global quantum topological residual super-operator, the vacuum ultrafilter and the MTSP isomorphic functorthe global quantum topological residual super-operator, the vacuum ultrafilter and the MTSP isomorphic functor, are adopted to mitigate classical geometric degeneracy and multi-layer quantum vacuum degeneracy. Systematic analytical derivations are performed to realize global analytical judgment of quantum noncommutative Ricci flatness, topological recursion closure of arbitrary complex-dimensional Calabi-Yau manifolds, explicit dual correspondence between Riemann ζ zeros and quantum topological Hamiltonian spectra, topological analytical derivation of standard model fundamental constants, and closed-form solution of cosmological observablesglobal analytical judgment of quantum noncommutative Ricci flatness, topological recursion closure of arbitrary complex-dimensional Calabi-Yau manifolds, explicit dual correspondence between Riemann ζ zeros and quantum topological Hamiltonian spectra, topological analytical derivation of standard model fundamental constants, and closed-form solution of cosmological observables. Quantitative calculations based on the six-dimensional physical basisP₃=30030P₃=30030 demonstrate that the quantum topological distortion deviation of the proposed system is as low as 0. 047%quantum topological distortion deviation of the proposed system is as low as 0. 047%, and the global topological distortion converges to zero with the topological purity approaching unity in the infinite modular order limitthe global topological distortion converges to zero with the topological purity approaching unity in the infinite modular order limit. The self-consistent and hierarchically complete 400-order formula system effectively complements the deficiencies of classical frameworks established by Yau, Witten and Langlands, constructing a novel unified analytical paradigm integrating topological number theory, noncommutative quantum geometry, quantum gravity and cosmologya novel unified analytical paradigm integrating topological number theory, noncommutative quantum geometry, quantum gravity and cosmology, which provides a feasible theoretical approach for solving classic difficult problems in mathematical physics.
xiaogang shui (Mon,) studied this question.