The hypothesis of a ninth planetary body emerged in response to unexplained orbital patterns in the outer Solar System. Trans-Neptunian Objects (TNOs) display orbital clustering, perihelion alignment, and semi-major axis distributions inconsistent with current gravitational models (NASA Astrobiology, n.d.). 

Traditionally, this has been attributed to the influence of an undiscovered massive planet - so-called Planet Nine. However, after years of extensive sky surveys and computational simulations, Planet Nine has eluded detection. This persistent absence invites a fundamental reassessment of our assumptions about mass, gravity, and structure in the Solar System. The NMSI framework responds to this challenge by proposing an alternative architecture: one based not on matter, but on informational logic and resonance.

Foundations of NMSI: A Logic-Based Physics

NMSI (New Subquantum Information Mechanics) redefines physical reality as a manifestation of infobitic oscillations - logic-based states propagating at subquantum scales (Quantum Dialectics Blog, 2025). In this framework, mass is not an intrinsic entity, but an emergent result of resonance between oscillating informational structures. Gravitational interactions are interpreted as stable antiphase couplings between logical cores - dynamic centers of subquantum coherence. Instead of viewing the Universe as a theater of forces and masses, NMSI describes a self-organizing system of logical oscillations, akin to a harmonic network sustained by phase relationships and structural symmetry. The CLO is the fundamental organizing entity - a non-material, oscillatory node defining the local logic of a gravitational structure without requiring mass or curvature.

Planet Nine as a CLO: The Antiphase Node

According to NMSI, the outer Solar System is stabilized by a CLO positioned in antiphase relative to the barycentric oscillation of the planetary system (NASA Astrobiology, n.d.). This CLO does not emit light, reflect radiation, or interact through known particle fields. Its presence is inferred purely through perturbative harmonics observed in the orbital behavior of TNOs.

Observed effects include

• Consistent alignment of perihelia across distinct objects,
• Eccentricity distortions matching a predictable harmonic envelope,
• Deviations from the expected gravitational influence of Neptune alone.

These effects can be mathematically modeled by antiresonance behavior stemming from an informational logical node (CLO) rather than from gravitational pull exerted by a material object.

Structural Oscillatory Logic of the Solar System

The Solar System, in NMSI terms, is not simply a heliocentric mass-driven configuration, but a hierarchy of CLOs, each sustaining its local system via resonance (NASA Astrobiology, n.d.). The Sun acts as the central oscillator of the barycentric field, while planets, moons, and planetary belts form nested subsystems of oscillatory logic. Planet Nine, in this model, functions not as a physical actor but as a stabilizing antiphase echo, ensuring balance through opposite-phase reinforcement. This explains the systemic coherence of remote objects without requiring exotic matter or unseen mass.

Replacing Dark Matter with Structural Resonance

One of the key implications of this model is the potential to reinterpret phenomena commonly attributed to dark matter (Kriger, n.d.). If gravitational anomalies across galaxies, clusters, and cosmic filaments can be modeled as logical CLO arrays in antiphase configuration, then dark matter becomes unnecessary as a physical component. Instead, it is replaced by a subquantum logical infrastructure - consistent, coherent, and stable. The Planet Nine CLO may therefore represent a local manifestation of a broader universal logical pattern, governing cosmic structures via resonance.

Predictive Model and Experimental Pathways

The NMSI model provides testable predictions:

• Perturbations in TNO orbits should align with quantized resonance bands, not mass-based gravitational curves.
• Any shift in the Solar Systems barycentric oscillation should result in measurable phase compensation in the Kuiper Belt (NASA Astrobiology, n.d.).
• CLOs, though non-material, may generate detectable spectral logic patterns in high-precision orbital simulations.

Future observational campaigns, such as the LSST project LSST (Legacy Survey of Space and Time) (n.d.), may offer indirect validation through long-term statistical analysis of orbital deviations. Moreover, artificial CLO resonators could be built in laboratory settings using electromagnetic oscillators, simulating similar antifazic behaviors and bridging cosmology with experimental subquantum physics.

Implications for Quantum Computing and Systemic AI

The architectural logic of Twin Quantum Computing (TQC), developed in parallel with NMSI, shares the same structural foundations proposed in this cosmological model. Each TQC node operates based on entangled oscillatory cores, interacting via phase dynamics. Understanding Planet Nine as a CLO informs the design of logic-based AI systems and resonance-driven computational architectures. In essence, natures logical structures - such as the Kuiper Belt CLO - become blueprints for artificial cognition. The Universe is not only observable but computable through oscillatory systems grounded in subquantum logic (Sharafi, 2023).

This paper offers a fundamental departure from the conventional gravitational paradigm. Instead of seeking hidden masses, it proposes hidden logic - resonance-based structures that stabilize systems through antifazic oscillations. Planet Nine is reinterpreted as a Logical Oscillating Core (CLO) embedded in the Kuiper Belt, maintaining orbital harmony without requiring visibility or mass-based inertia. By embracing informational logic as the substrate of cosmic structure, the NMSI model invites a new class of explanations for cosmic anomalies - from Solar System dynamics to galactic halos - while simultaneously opening pathways for the development of new computation models and unified field theories.

The author thanks the Universe Publishing Group for the opportunity to submit and publish this work.

The author declares no conflict of interest.