Elimination of Re-entry Thermal Protection Systems via Granular Drag Collapse and Regimental Quantum Transition (QRT) Article Swipe
SOBRAL, DIOGENES DUARTE
·
YOU?
·
· 2025
· Open Access
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· DOI: https://doi.org/10.5281/zenodo.17715164
YOU?
·
· 2025
· Open Access
·
· DOI: https://doi.org/10.5281/zenodo.17715164
(DOI: 10.5281/zenodo.17715165) Português (título e resumo oficial) Título: Eliminação dos Escudos Térmicos de Reentrada via Colapso do Arrasto Granular e Transição Quântica Regimental (QRT) Autor: Diógenes Duarte Sobral (MeshWave Foundation – Rio de Janeiro, Brasil) Data: 26 de novembro de 2025 Resumo: A Teoria do Multifluxo prevê que, acima do limiar crítico de Mach 12–15, o número de subfluxos energeticamente relevantes colapsa de N(t) > 100 para N(t) → 1. Esse colapso provoca a eliminação completa do arrasto granular e a formação de um estado pós-choque coerente quântico — a Transição Quântica Regimental (QRT). Como consequência direta, o fluxo de calor convectivo cai mais de uma ordem de grandeza, tornando fisicamente obsoletos os escudos térmicos tradicionais (PICA-X, tiles de 70 toneladas). Resultados qDSMC confirmam espessura de choque reduzida de ~120 λ para 18–25 λ e ganho de payload da Starship de +44 % (150 t → 216 t) apenas pela eliminação do TPS. Este trabalho representa o certificado de óbito definitivo dos escudos térmicos de dezenas de toneladas em veículos de reentrada hipersônica. English (official title and abstract) Title: Elimination of Re-entry Thermal Protection Systems via Granular Drag Collapse and Regimental Quantum Transition (QRT) Author: Diógenes Duarte Sobral (MeshWave Foundation – Rio de Janeiro, Brazil) Date: November 26, 2025 DOI: 10.5281/zenodo.17715165 Abstract: Multiflux Theory predicts that above the critical Mach 12–15 threshold, the number of energetically relevant subflows collapses from N(t) > 100 to N(t) → 1. This collapse triggers the complete elimination of granular drag and the emergence of a quantum-coherent post-shock state — the Regimental Quantum Transition (QRT). As a direct consequence, convective heat flux drops by more than one order of magnitude, rendering traditional thermal protection systems (PICA-X, 70-tonne tiles) physically obsolete. Quantum-corrected DSMC (qDSMC) simulations confirm shock thickness reduction from ~120 λ to 18–25 λ and a Starship payload increase of +44 % (150 t → 216 t) achieved solely by eliminating the TPS. For the first time in astronautics history, this paper mathematically proves and numerically demonstrates that multi-ton re-entry heat shields are no longer physically necessary. Palavras-chave / Keywords: Multiflux Theory, Regimental Quantum Transition, QRT, hypersonic drag collapse, TPS elimination, Starship payload gain, quantum-coherent shock layer, qDSMC Licença acadêmica: CC BY-NC-SA 4.0 Licenças comerciais: [email protected] Série completa / Full series: https://zenodo.org/communities/multiflux/
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https://openalex.org/W7106666389Canonical identifier for this work in OpenAlex
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https://doi.org/10.5281/zenodo.17715164Digital Object Identifier
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Elimination of Re-entry Thermal Protection Systems via Granular Drag Collapse and Regimental Quantum Transition (QRT)Work title
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articleOpenAlex work type
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2025Year of publication
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2025-11-25Full publication date if available
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SOBRAL, DIOGENES DUARTEList of authors in order
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YesWhether a free full text is available
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greenOpen access status per OpenAlex
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https://doi.org/10.5281/zenodo.17715164Direct OA link when available
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Mach number, Drag, Physics, Granular material, Heat flow, Thermal, Thermal state, Mechanics, Thermodynamics, Thermal protection, Materials science, Humanities, Foundation (evidence), Stagnation pointTop concepts (fields/topics) attached by OpenAlex
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| abstract_inverted_index.Re-entry | 181 |
| abstract_inverted_index.Starship | 139, 301, 356 |
| abstract_inverted_index.Título: | 7 |
| abstract_inverted_index.achieved | 312 |
| abstract_inverted_index.coerente | 86 |
| abstract_inverted_index.collapse | 238 |
| abstract_inverted_index.completa | 75, 372 |
| abstract_inverted_index.complete | 241 |
| abstract_inverted_index.critical | 218 |
| abstract_inverted_index.crítico | 51 |
| abstract_inverted_index.granular | 78, 244 |
| abstract_inverted_index.history, | 324 |
| abstract_inverted_index.increase | 303 |
| abstract_inverted_index.novembro | 38 |
| abstract_inverted_index.oficial) | 6 |
| abstract_inverted_index.predicts | 214 |
| abstract_inverted_index.re-entry | 334 |
| abstract_inverted_index.reduzida | 127 |
| abstract_inverted_index.relevant | 226 |
| abstract_inverted_index.subflows | 227 |
| abstract_inverted_index.tornando | 109 |
| abstract_inverted_index.trabalho | 154 |
| abstract_inverted_index.triggers | 239 |
| abstract_inverted_index.(MeshWave | 28, 198 |
| abstract_inverted_index.(official | 174 |
| abstract_inverted_index.Abstract: | 211 |
| abstract_inverted_index.Diógenes | 25, 195 |
| abstract_inverted_index.Keywords: | 344 |
| abstract_inverted_index.Licenças | 368 |
| abstract_inverted_index.Multiflux | 212, 345 |
| abstract_inverted_index.Quântica | 21, 91 |
| abstract_inverted_index.Reentrada | 13 |
| abstract_inverted_index.Térmicos | 11 |
| abstract_inverted_index.abstract) | 177 |
| abstract_inverted_index.collapse, | 353 |
| abstract_inverted_index.collapses | 228 |
| abstract_inverted_index.confirmam | 123 |
| abstract_inverted_index.emergence | 248 |
| abstract_inverted_index.espessura | 124 |
| abstract_inverted_index.grandeza, | 108 |
| abstract_inverted_index.multi-ton | 333 |
| abstract_inverted_index.obsolete. | 284 |
| abstract_inverted_index.obsoletos | 111 |
| abstract_inverted_index.quântico | 87 |
| abstract_inverted_index.reduction | 292 |
| abstract_inverted_index.reentrada | 171 |
| abstract_inverted_index.rendering | 275 |
| abstract_inverted_index.subfluxos | 58 |
| abstract_inverted_index.thickness | 291 |
| abstract_inverted_index.toneladas | 167 |
| abstract_inverted_index.térmicos | 114, 163 |
| abstract_inverted_index.veículos | 169 |
| abstract_inverted_index.Foundation | 29, 199 |
| abstract_inverted_index.Multifluxo | 45 |
| abstract_inverted_index.Português | 2 |
| abstract_inverted_index.Protection | 183 |
| abstract_inverted_index.Regimental | 22, 92, 190, 256, 347 |
| abstract_inverted_index.Resultados | 121 |
| abstract_inverted_index.Transition | 192, 258 |
| abstract_inverted_index.convective | 264 |
| abstract_inverted_index.convectivo | 101 |
| abstract_inverted_index.definitivo | 160 |
| abstract_inverted_index.formação | 81 |
| abstract_inverted_index.hypersonic | 351 |
| abstract_inverted_index.magnitude, | 274 |
| abstract_inverted_index.necessary. | 341 |
| abstract_inverted_index.physically | 283, 340 |
| abstract_inverted_index.post-shock | 252 |
| abstract_inverted_index.protection | 278 |
| abstract_inverted_index.relevantes | 60 |
| abstract_inverted_index.representa | 155 |
| abstract_inverted_index.threshold, | 221 |
| abstract_inverted_index.Elimination | 179 |
| abstract_inverted_index.Transition, | 349 |
| abstract_inverted_index.Transição | 20, 90 |
| abstract_inverted_index.acadêmica: | 364 |
| abstract_inverted_index.certificado | 157 |
| abstract_inverted_index.comerciais: | 369 |
| abstract_inverted_index.eliminating | 315 |
| abstract_inverted_index.elimination | 242 |
| abstract_inverted_index.fisicamente | 110 |
| abstract_inverted_index.numerically | 330 |
| abstract_inverted_index.pós-choque | 85 |
| abstract_inverted_index.simulations | 288 |
| abstract_inverted_index.toneladas). | 120 |
| abstract_inverted_index.traditional | 276 |
| abstract_inverted_index.Eliminação | 8 |
| abstract_inverted_index.astronautics | 323 |
| abstract_inverted_index.consequence, | 263 |
| abstract_inverted_index.demonstrates | 331 |
| abstract_inverted_index.elimination, | 355 |
| abstract_inverted_index.eliminação | 74, 150 |
| abstract_inverted_index.tradicionais | 115 |
| abstract_inverted_index.consequência | 95 |
| abstract_inverted_index.energetically | 225 |
| abstract_inverted_index.hipersônica. | 172 |
| abstract_inverted_index.Palavras-chave | 342 |
| abstract_inverted_index.mathematically | 327 |
| abstract_inverted_index.energeticamente | 59 |
| abstract_inverted_index.quantum-coherent | 251, 359 |
| abstract_inverted_index.Quantum-corrected | 285 |
| [email protected] | 370 |
| abstract_inverted_index.10.5281/zenodo.17715165 | 210 |
| abstract_inverted_index.10.5281/zenodo.17715165) | 1 |
| abstract_inverted_index.https://zenodo.org/communities/multiflux/ | 376 |
| cited_by_percentile_year | |
| countries_distinct_count | 1 |
| institutions_distinct_count | 1 |
| citation_normalized_percentile.value | 0.7880361 |
| citation_normalized_percentile.is_in_top_1_percent | False |
| citation_normalized_percentile.is_in_top_10_percent | False |