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| Format: | Recurso digital |
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Zenodo
2026
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| Online Access: | https://doi.org/10.5281/zenodo.20073734 |
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Table of Contents:
- <p>## ABSTRACT: Design and Validation of a Super-Rigid Aperiodic Monolith (NSRS-M v12.18-OsB)<br>This report documents the final theoretical synthesis and numerical validation of a high-density, super-rigid metallic composite utilizing an aperiodic lattice structure. The NSRS-M v12.18-OsB model integrates extreme material parameters—specifically Osmium (Os) and Boron-based covalent phases—within a seven-layer Fibonacci sequence (W, Os, B, Mo, Pt, Au, Ti).<br>The core of the system is defined by a unified state integral of coherence, stabilized by a geometric "seal" constant $\kappa_{\Phi} = \Phi^8 \approx 46.9787$. This specific normalization factor was identified as the only mathematical solution capable of suppressing numerical divergence induced by the extreme binding energy of the osmium-boride matrix. Furthermore, the inclusion of a quartic nonlinear impedance operator $(\mathbf{J} \cdot \mathbf{Z})^4$ establishes a state of antifragility, where structural integrity scales exponentially with increasing external impedance.<br>Ultimate forensic audits conducted in the MATLAB environment confirmed an effective Young's modulus of 114.96 GPa and a 100% quantum coherence match. Stress tests involving log-scale impedance spikes demonstrated absolute structural stability, classifying the system as a Static Monolith with zero internal entropy at the singular limit ($t \to 0$). The model is mathematically robust, physically realizable within the limits of advanced metallurgy, and ready for technical implementation in environments requiring total resonance immunity and extreme impact resistance.<br>Keywords: Aperiodic lattices, Fibonacci sequence, Osmium-Boride structures, Nonlinear elastodynamics, Static Monolith, NSRS-M v12.18-OsB.</p>