This paper systematically establishes P-adic Operational Mathematics as a rigorously axiomatized discipline whose core program is the extension of the repetition count of fundamental mathematical operations on the p-adic field Qₚ from natural numbers to integers, rational numbers, real p-adic numbers, and ultimately to complex numbers, while simultaneously treating inverse operations as fundamental objects of equal status. We establish a complete axiomatic system consisting of six logically independent axioms, each precisely reflecting the essential features of p-adic analysis: the ultrametric inequality, Hensel's lemma and p-adic integrality, finite convergence radii of the p-adic exponential and logarithm, the canonicity of Teichm\"uller representatives, rigid analytic spaces and Tate algebras, and p-adic Galois theory via (, ) -modules. Building upon this foundation, we develop a comprehensive theory encompassing: the pro-p group structure of integer-order iterations and their connection to Lubin-Tate formal groups; the rigorous construction of p-adic Schr\"oder and Abel functions with precise p-adic integrality estimates and closed-form Bell polynomial expressions; the complete classification of parabolic fixed points; the p-adic Kneser-type construction of real-order tetration, proving existence and uniqueness over the entire Zₚ without branch cuts; analytic continuation to complex orders with complete singularity analysis and connection to p-adic modular forms of weight 2; the unification of p-adic differential, integral, finite difference, and summation operators into a single analytic semigroup \O^\_; a p-adic fractional calculus of variations with Euler-Lagrange equations and complete Noether theory; the rigorous construction of a continuous p-adic hyperoperation spectrum with proof of a No-Go theorem establishing the structural necessity of piecewise construction; the complete inductive construction of higher-order p-adic hyperoperations (n 3), proving universality of the attracting fixed point and multiplier across all levels. We reveal a profound duality between P-adic Operational Mathematics and the Galois theory of local fields, formalized as a categorical equivalence between the delooping of the p-adic iteration group and that of the additive group Zₚ, extended to higher-dimensional abelian varieties and lifted to the -categorical level. The p-adic discrete logarithm is identified as the inverse duality map, and the Schr\"oder function is classified as a rank-1 \'etale (, ) -module. We construct fractional Frobenius endomorphisms on \'etale cohomology and define a continuous Hasse-Weil zeta function X (t, s) with a global functional equation. The Riemann hypothesis of the Weil conjectures is equivalently reformulated in terms of the continuous spectrum. The Noether invariant of a p-adic fractional variational problem is proved to coincide precisely with the N\'eron-Tate height, and the Mellin transform of the tetrational modular form shares the zero-pole structure with the zeta function of an Artin-Schreier variety. Exponentially convergent numerical algorithms based on p-adic Newton iteration are developed with rigorous a priori and a posteriori error bounds, and complete numerical verification data is provided. Cryptographic applications yield post-quantum secure depth-based Diffie-Hellman protocols, with an unconditional quantum query lower bound of (^1/3) proved for the iteration depth problem when n 3. Fractional quantum algorithms with noise resilience guarantees are designed. The global Riemann surface of the hyperoperation spectrum is constructed, the tropical limit is rigorously derived, and a concrete physical realization in p-adic supersymmetric quantum mechanics is established. All conjectures and open problems are transformed into rigorously proved theorems and organically integrated into the body of the paper.
Liu S (Wed,) studied this question.
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