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| Format: | Recurso digital |
| Language: | English |
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2025
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| Online Access: | https://doi.org/10.5281/zenodo.17910530 |
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| _version_ | 1866901904636772352 |
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| author | Ken, Fukura |
| author_facet | Ken, Fukura |
| contents | <p> This paper proposes Parallel Scale-Shift Cosmology, a framework based on the<br> hypothesis that the gravitational environment of an observer and the associated<br> time dilation induce a relative transformation of spatial scales (“scale-shifts”).<br> This mechanism offers a unified interpretation of several unresolved problems in<br> cosmology. When an observer moves into a higher-gravity region, time dilation<br> reduces the effective upper limit of observable speeds. As a result, regions<br> that were formerly observable retreat beyond the observational boundary, while<br> different regions become newly visible as past states. Within this framework,<br> cosmic inflation is reinterpreted not as a physical superluminal expansion but<br> as an apparent phenomenon emerging from observational scale transformations.<br> Thetheory builds on the observational principle that light defines the observabil<br>ity of existence. In this view, inflation arises from the dual structure between<br> quantum-level physical reality and relativistic phenomenological appearance.<br> Black holes, in turn, manifest as an expansion of unobservable domains to an<br> external observer, while their internal structures may connect smoothly to al<br>ternative observational frames. Scale-shifts of the observer frame could make<br> the entire universe appear as an extended, white-hole–like region inside a su<br>permassive black hole.<br> Furthermore, statistical considerations imply that an increased density of black<br> holes toward the infinite distance deforms an observer’s causal domain gravita<br>tionally, selectively elongating spatial scales along directions where light remains<br> reachable. This perspective reframes cosmic expansion as a consequence induced<br> by the properties of the observer’s frame.<br> The structure of unobservable domains shared among multiple observers may<br> also produce a “shared contradiction region,” potentially explaining phenomena<br> such as simultaneous inventions and the Mandela effect. The proposed frame<br>work provides multilayered, self-consistent interpretations of the information<br>loss problem, Olbers’ paradox, and the cosmological constant problem. Alto<br>gether, it offers a foundation for a unified understanding of observation, gravity,<br> time, and scale.</p> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_17910530 |
| institution | Zenodo |
| language | eng |
| publishDate | 2025 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | ParallelScale-ShiftCosmology Ken, Fukura Physics <p> This paper proposes Parallel Scale-Shift Cosmology, a framework based on the<br> hypothesis that the gravitational environment of an observer and the associated<br> time dilation induce a relative transformation of spatial scales (“scale-shifts”).<br> This mechanism offers a unified interpretation of several unresolved problems in<br> cosmology. When an observer moves into a higher-gravity region, time dilation<br> reduces the effective upper limit of observable speeds. As a result, regions<br> that were formerly observable retreat beyond the observational boundary, while<br> different regions become newly visible as past states. Within this framework,<br> cosmic inflation is reinterpreted not as a physical superluminal expansion but<br> as an apparent phenomenon emerging from observational scale transformations.<br> Thetheory builds on the observational principle that light defines the observabil<br>ity of existence. In this view, inflation arises from the dual structure between<br> quantum-level physical reality and relativistic phenomenological appearance.<br> Black holes, in turn, manifest as an expansion of unobservable domains to an<br> external observer, while their internal structures may connect smoothly to al<br>ternative observational frames. Scale-shifts of the observer frame could make<br> the entire universe appear as an extended, white-hole–like region inside a su<br>permassive black hole.<br> Furthermore, statistical considerations imply that an increased density of black<br> holes toward the infinite distance deforms an observer’s causal domain gravita<br>tionally, selectively elongating spatial scales along directions where light remains<br> reachable. This perspective reframes cosmic expansion as a consequence induced<br> by the properties of the observer’s frame.<br> The structure of unobservable domains shared among multiple observers may<br> also produce a “shared contradiction region,” potentially explaining phenomena<br> such as simultaneous inventions and the Mandela effect. The proposed frame<br>work provides multilayered, self-consistent interpretations of the information<br>loss problem, Olbers’ paradox, and the cosmological constant problem. Alto<br>gether, it offers a foundation for a unified understanding of observation, gravity,<br> time, and scale.</p> |
| title | ParallelScale-ShiftCosmology |
| topic | Physics |
| url | https://doi.org/10.5281/zenodo.17910530 |