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Zenodo
2025
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| Accesso online: | https://doi.org/10.5281/zenodo.18445323 |
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| _version_ | 1866902136445468672 |
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| author | Lemeshko, Andriy |
| author_facet | Lemeshko, Andriy |
| contents | <h2><strong><span>Abstract</span></strong></h2> <p>This paper proposes a diagnostic reinterpretation of gravitational and thrust-related anomalies within the framework of temporal gradients, as developed in the Temporal Theory of the Universe (TTU). Rather than introducing new forces or modifying established dynamics, the approach reframes a broad class of anomalous observations as responses to spatial and temporal variations in the local rate of time flow.</p> <p>Building on well-tested relativistic time dilation effects, gravity is interpreted as a manifestation of a temporal gradient <span>∇</span>τ, toward which matter naturally drifts. This perspective remains fully compatible with General Relativity at the level of observable predictions, including classical tests such as Mercury’s perihelion precession, while offering an alternative ontological interpretation of gravitational interaction.</p> <p>The paper surveys experimental environments in which temporal-gradient effects may be diagnostically probed, including deep-space missions (e.g., Pioneer 10/11, Juno), precision laboratory experiments (atomic clocks, antimatter free-fall tests), and resonant electromagnetic systems commonly referred to as EMDrive-type setups. Within TTU, such systems are not treated as propulsion devices but as metastable, noise-dominated environments that may transiently amplify temporal anisotropies.</p> <p>Engineering-level estimates are provided to illustrate the expected magnitude and fragility of temporal-gradient effects, emphasizing their sensitivity to entropy, decoherence, and environmental noise. The central claim is modest but concrete: existing technologies already operate within the sensitivity range required to detect temporal gradients, and several reported anomalies can be consistently reinterpreted as diagnostic signatures of temporal-field structure rather than as evidence of exotic forces.</p> <div> </div> <h2><strong><span>Keywords</span></strong></h2> <p>temporal gradients; gravity diagnostics; anomalous thrust; time dilation; Temporal Theory of the Universe; EMDrive-type experiments; Pioneer anomaly; atomic clocks; non-reproducibility; General Relativity reinterpretation</p> <h3> </h3> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_18445323 |
| institution | Zenodo |
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| publishDate | 2025 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | Temporal Gradients as a Diagnostic Framework for Gravitational and Thrust Anomalies Lemeshko, Andriy <h2><strong><span>Abstract</span></strong></h2> <p>This paper proposes a diagnostic reinterpretation of gravitational and thrust-related anomalies within the framework of temporal gradients, as developed in the Temporal Theory of the Universe (TTU). Rather than introducing new forces or modifying established dynamics, the approach reframes a broad class of anomalous observations as responses to spatial and temporal variations in the local rate of time flow.</p> <p>Building on well-tested relativistic time dilation effects, gravity is interpreted as a manifestation of a temporal gradient <span>∇</span>τ, toward which matter naturally drifts. This perspective remains fully compatible with General Relativity at the level of observable predictions, including classical tests such as Mercury’s perihelion precession, while offering an alternative ontological interpretation of gravitational interaction.</p> <p>The paper surveys experimental environments in which temporal-gradient effects may be diagnostically probed, including deep-space missions (e.g., Pioneer 10/11, Juno), precision laboratory experiments (atomic clocks, antimatter free-fall tests), and resonant electromagnetic systems commonly referred to as EMDrive-type setups. Within TTU, such systems are not treated as propulsion devices but as metastable, noise-dominated environments that may transiently amplify temporal anisotropies.</p> <p>Engineering-level estimates are provided to illustrate the expected magnitude and fragility of temporal-gradient effects, emphasizing their sensitivity to entropy, decoherence, and environmental noise. The central claim is modest but concrete: existing technologies already operate within the sensitivity range required to detect temporal gradients, and several reported anomalies can be consistently reinterpreted as diagnostic signatures of temporal-field structure rather than as evidence of exotic forces.</p> <div> </div> <h2><strong><span>Keywords</span></strong></h2> <p>temporal gradients; gravity diagnostics; anomalous thrust; time dilation; Temporal Theory of the Universe; EMDrive-type experiments; Pioneer anomaly; atomic clocks; non-reproducibility; General Relativity reinterpretation</p> <h3> </h3> |
| title | Temporal Gradients as a Diagnostic Framework for Gravitational and Thrust Anomalies |
| url | https://doi.org/10.5281/zenodo.18445323 |