Modern cosmology faces fundamental puzzles: the nature of dark energy, the origin of the cosmological constant, the cosmic coincidence problem, and the mass hierarchy problem. In this work, a new theoretical paradigm is proposed — the Chronosphere — in which the observable Universe is a three-dimensional sphere (the horizon), and its boundary acts as an ontological operator T responsible for the actualization of quantum states. The mathematical framework is borrowed from Goro Kato's t-topos formalism, allowing a rigorous translation of categorical structures (objects "Nothing", "Something" and morphisms) into the language of physics. Based on the proposed axiomatics and the Atiyah-Patodi-Singer theorem for a family of Dirac operators on the Euclidean ball B4 with boundary S3, a topological prediction for the dark energy parameter is obtained: atop=9/(4π), corresponding to ΩΛ ≈ 0.24. This value does not agree with observations, indicating the need for quantum-dynamical corrections. A hypothesis is put forward that the renormalization group flow (within the functional renormalization group framework and the concept of essential couplings) from the ultraviolet fixed point τ∗=atopτ∗=atop to the infrared limit generates an integral factor F(ξ) = π, leading to the final a=9/4 (ΩΛ=0.75). Thus the theory predicts a rigid relation ΩΛ/Ωm=3, an equation of state w ≈ − 0.953, and a tensor-to-scalar ratio r ≈ 0.002, accessible to tests in experiments of the coming decade (Euclid, DESI, CMB-S4, SKA). The paper lays an axiomatic foundation, details the topological derivation, and formulates a concrete research program aimed at a rigorous computation of the renormalization group factor, completing the Chronosphere theory.
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