Arithmetic Power Geometry (APG) is an emerging mathematical framework for studying structural deformation under continuous exponent variation. Instead of fixing the exponent in a power relation and varying only the coordinates, APG treats the exponent itself as a deformation parameter. This shift transforms algebraic closure from a binary question of existence into a quantitative question of structural change. The foundational APG construction introduces the Power-Deformation Space, the Euclidean Target, the Local Closure Defect, normalized Euclidean weights, and the entropy-controlled first-order deformation law. The central local result states that the initial closure defect near the Euclidean baseline is governed by the Shannon entropy of the normalized coordinate weights. This paper rebuilds the APG program as a readable framework, tutorial, and research roadmap. It explains the conceptual motivation of APG, its relationship with arithmetic geometry, information geometry, deformation theory, spectral theory, and machine learning, and its practical methodology for new domains. The paper also summarizes demonstrated applications in adaptive metric search, financial fraud analysis, blockchain networks, materials out-of-distribution screening, and high-dimensional information systems. It then presents future research directions in artificial intelligence, optimization, healthcare, biology, materials science, physics, climate modelling, transportation, cybersecurity, economics, and mathematics. The paper does not claim that APG replaces existing theories or provides universal superiority over established methods. Instead, it positions APG as a transparent mathematical language for reference states, normalized structural weights, entropy, deformation, and closure defects. The intended contribution is to provide students, researchers, and practitioners with a clear entry point for understanding, testing, extending, and applying APG.
Md. Amir Khusru Akhtar (Sat,) studied this question.