Proposals to Recalibration and Dynamics in Earth's Rotation: Through the lens of ITF

Proposals to Recalibration and Dynamics in Earth's Rotation: Through the lens of ITF | Authorea try { document.documentElement.classList.add('js'); } catch (e) { } var _gaq = _gaq || []; _gaq.push(['_setAccount', 'G-8VDV14Y67G']); _gaq.push(['_trackPageview']); (function() { var ga = document.createElement('script'); ga.type = 'text/javascript'; ga.async = true; ga.src = ('https:' == document.location.protocol ? 'https://ssl' : 'http://www') + '.google-analytics.com/ga.js'; var s = document.getElementsByTagName('script')[0]; s.parentNode.insertBefore(ga, s); })(); Skip to main content Preprints Collections Wiley Open Research IET Open Research Ecological Society of Japan All Collections About About Authorea FAQs Contact Us Quick Search anywhere Search for preprint articles, keywords, etc. Search Search ADVANCED SEARCH SCROLL This is a preprint and has not been peer reviewed. Data may be preliminary. 21 January 2026 V2 Latest version Share on Proposals to Recalibration and Dynamics in Earth's Rotation: Through the lens of ITF Author : Bruno Wayne Salter 0000-0003-2643-3229 [email protected] Authors Info & Affiliations https://doi.org/10.22541/au.176858288.85445114/v2 438 views 133 downloads Contents Abstract Supplementary Material Information & Authors Metrics & Citations View Options References Figures Tables Media Share Abstract This current work presents a hypothesis and evidence for electromagnetic couplingbetween Earth’s rotational and magnetic axes alongside emerged anomalies as theprimary mechanism sustaining planetary rotation against tidal friction losses. Theoptimal coupling angle of 13 derives from the Informational Topography Field (ITF)lattice displacement ratio δ= 0.13, a fundamental geometric constant governing space-time structure and, supposedly, a continuous self-recycling energy model. Analysis ofmagnetic pole position data spanning 1900-2023 reveals statistically significant cor-relation (Pearson r = 0.534, p = 0.0401) between deviation from this optimal angleand magnetic pole velocity, pointing to the theoretical prediction and proposal. Thesystem achieved maximum coupling efficiency in 1990 when the magnetic axis was po-sitioned at 11.7 from the rotational axis, representing the closest historical approachto the theoretical optimum. Current deviation of 9.2 correlates with unprecedentedmagnetic pole acceleration of 58.4 km/year, representing a 4.2-fold increase over the1900-1980 historical average. We propose Earth undergoes periodic electromagneticrecalibration events triggered by coupling degradation beyond critical thresholds, man-ifesting as crustal fracturing, deep hydrate expulsion, continental reorganization, andbiological transitions. Quantitative analysis of recalibration dynamics incorporatingelectromagnetic damping, viscous coupling at the core-mantle boundary, and potentialresonant oscillator mechanisms indicates transition timescales of months to years fol-lowing threshold crossing. The ITF lattice framework (SALTER, 2025) explains thesephenomena through geometric first principles, offering a unified model connecting cos-mological structure formation, planetary electromagnetic dynamics, ocean chemistryevolution, and biological cycles. The core hypothesis proposes ultra-high-pressure hy-drated silicate phases rather than iron-nickel composition purely, with piezoelectricfield generation providing direct coupling between rotational stress and magnetic fieldevolution. Periodic dehydration events expel water and dissolved halides to the surface,explaining oceanic chloride excess and providing the mineralogical and chemical ba-sis for renewed organic synthesis. Statistical extrapolation of current trends indicatescontinued system instability through 2026-2027, with testable predictions for observ-able electromagnetic phenomena, seismic activity patterns, and rotational anomalies.This current framework provides falsifiable criteria distinguishing it from standardgeodynamo models. Supplementary Material File (yy5.pdf) Download 337.65 KB Information & Authors Information Version history V1 Version 1 16 January 2026 V2 Version 2 21 January 2026 Copyright This work is licensed under a Non Exclusive No Reuse License. Keywords electromagnetism polarity polarity reversal rotation solar system Authors Affiliations Bruno Wayne Salter 0000-0003-2643-3229 [email protected] Independent Researcher São Paulo View all articles by this author Metrics & Citations Metrics Article Usage 438 views 133 downloads .FvxKWukQNSOunydq8rnd { width: 100px; } Citations Download citation Bruno Wayne Salter. Proposals to Recalibration and Dynamics in Earth's Rotation: Through the lens of ITF. Authorea . 21 January 2026. DOI: https://doi.org/10.22541/au.176858288.85445114/v2 If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download. For more information or tips please see 'Downloading to a citation manager' in the Help menu . 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