The deployment of the James Webb Space Telescope (JWST) has helped inaugurate a new era of high-precision cosmological observation, occasionally challenging established timelines of galactic evolution. The observation of the massive, quiescent galaxy XMM-VID1-2075, located merely 1.8 billion years after Dimensional Genesis, presents a profound mechanical paradox. Operating as a "slow-rotator" almost entirely devoid of significant angular momentum, its mature structural state appears to defy classical kinetic models, which traditionally require billions of years of mechanical mergers to dissipate such immense rotational energy. This fourth working paper of the Asymmetric Temporal Wave (ONA) Theory proposes a systemic resolution to this paradox. By proposing a redefinition of the spatial matrix as an active, ever-generating topological network and exploring the reinterpretation of matter as concentrated densities of temporal sub-waves, we introduce the concept of Informational Friction (σ). In the highly dense primordial universe, the relentless effort of sub-waves to synchronize and maintain phase coherence against the rapid expansion of the matrix is hypothesized to generate a profound phase resistance that acts as a localized topological brake. This intrinsic friction is proposed to efficiently dissipate coordinated angular momentum and trigger early structural quenching without necessarily requiring prolonged external kinetic collisions. Rather than fracturing the standard cosmological model, the introduction of wave-based thermodynamic processing aims to expand our analytical vocabulary, offering a unified, scalable matrix of state transitions capable of elegantly interpreting the JWST's most complex primordial observations.
José Pedro Gonçalves (Sun,) studied this question.
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