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| Format: | Recurso digital |
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Zenodo
2026
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| Matèries: | |
| Accés en línia: | https://doi.org/10.5281/zenodo.19297313 |
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- <p><span lang="EN-US">This paper presents a complete technical justification for the experiment on the detection of the </span><span>τ</span><span lang="EN-US">-field, the fundamental time field, the existence of which is predicted by our theory. In contrast to classical approaches using Wilczek time crystals, we propose a fundamentally new architecture based on <strong>a diffraction nano-grid</strong> as a passive resonator of the subharmonics of the </span><span>τ</span><span lang="EN-US">-field. This solution eliminates the fundamental limitations associated with thermal noise and lattice defects and achieves the required phase measurement accuracy of </span><span>Δφ</span><span lang="EN-US"> < 10⁻¹⁰ rads.</span></p> <p><span lang="EN-US">The key element of the experiment is <strong>a heterodyne system with digital phase-locked frequency (PLL)</strong> based on the universal phase synchronization algorithm developed by us. The algorithm provides deterministic synchronization instead of statistical expectation, which radically changes the time scales of the experiment — from "billions of years" to nanoseconds.</span></p> <p><strong><span>Main parameters:</span></strong></p> <ul> <li><span lang="EN-US">Operating frequency: 1.416 THz (proton-electron pair subharmonic)</span></li> <li><span lang="EN-US">Electronics reference: 14.16 GHz (divided by 100)</span></li> <li><span lang="EN-US">Synchronization accuracy: </span><span>Δφ</span><span lang="EN-US"> < 10⁻¹⁰ rads in 50 ns</span></li> <li><span>Measured quantity: χ = φ·τ (chronal quantum)</span></li> </ul> <p><span lang="EN-US">Resonator: nano-grid with a period multiple of </span><span>λ</span><span lang="EN-US">/2</span></p>