While current frameworks in cosmology and theoretical physics have provided profound insights into the nature of the universe, emerging observational data increasingly invites new systemic perspectives. This working paper introduces the Asymmetric Temporal Wave (ONA) Theory, an exploratory conceptual architecture that proposes a shift from an object-oriented universe to a process-oriented cosmology. The theory suggests modeling the cosmos as a continuous, self-optimizing system governed by a unified mathematical identity: Ψ(t) = Φt · eΩt · Γ. By redefining space as an active topological amplitude that dynamically manages informational friction (-σ) generated by the continuous forward propagation of a temporal wave, the ONA framework offers cohesive, mechanics-based resolutions for several astronomical anomalies. These include the underlying mechanisms of inertia, the cohesion of dark matter, the Hubble Tension, and the absence of primordial antimatter. Furthermore, the framework extends beyond retrospective analysis to introduce a falsifiable predictive cosmology, anticipating macroscopic signatures such as Vectorial Bandwidth Anisotropy and Orphan Friction Nodes. Offered as an open, foundational blueprint, this paper invites the global scientific community to collaboratively explore, test, and expand upon these concepts for the advancement of a unified cosmic understanding.
José Pedro Gonçalves (Mon,) studied this question.