{"data":[{"id":"10.5281/zenodo.18908377","type":"dois","attributes":{"doi":"10.5281/zenodo.18908377","identifiers":[{"identifier":"oai:zenodo.org:18908377","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XII: Force Distribution, Boundary Parameters, and the Mechanics of Intimacy Entry"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"boundary parameters"},{"subject":"force distribution"},{"subject":"adolescent recalibration"},{"subject":"steady-state intimacy"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"computational intimacy model"},{"subject":"Visibility"},{"subject":"V"},{"subject":"G"},{"subject":"Gate sensitivity"},{"subject":"Alarm threshold"},{"subject":"A_th"},{"subject":"paternal delayed-entry"},{"subject":"parameter convergence"},{"subject":"strong father weak mother"},{"subject":"strong mother weak father"},{"subject":"Alarm-dominant boundary"},{"subject":"Gate-dominant boundary"},{"subject":"structural deficit"},{"subject":"Delta"},{"subject":"Δ"},{"subject":"intimacy entry mechanics"},{"subject":"force-signature compatibility"},{"subject":"non-intrusive entry"},{"subject":"boundary-parameter origin"}],"contributors":[],"dates":[{"date":"2026-03-08","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18865281","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18886969","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18907595","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18908376","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 12\n\nWhy do intimate boundaries form the way they do – not as a result of conscious choice, attachment history, or personality, but as a mechanical consequence of early force distribution? Existing computational models of social behaviour treat boundary formation as learned from reinforcement, shaped by attachment parameters, or encoded as social norms. They cannot explain why the system computes its baseline Visibility (V), Spotlight sensitivity (S), and Alarm threshold from parental force asymmetry, why these parameters remain floating until adolescence, or why intimacy entry is determined by structural deficit matching rather than by preference or liking.\n\nVolume 12 of Symbolic Mechanics formalises boundary formation as a two‑stage mechanical computation. The system does not generate personality from parents. It computes boundary parameters from force distribution. The first mapping occurs after paternal delayed entry, when force becomes legible. The second calibration occurs during adolescence, when the system re‑tests every early assumption and fixes V, S, and Alarm into permanent baselines.\n\nThe initial force distribution produces two canonical boundary configurations:\n\n· Strong Father / Weak Mother → Alarm‑dominant. The boundary contracts at minimal input, opens only to softness, and treats all force‑shaped signals as intrusion vectors. Visibility remains structurally self‑protective.· Strong Mother / Weak Father → Spotlight‑dominant. The boundary opens easily under softness, rarely closes in response to force, and exhibits low Alarm sensitivity. Visibility tends toward low structural discipline.\n\nIn adulthood, intimacy entry is determined by three fixed parameters: V (structural capacity), S (gating threshold), and Alarm (intrusion classifier). Entry occurs only when the incoming signal matches the system’s structural deficit (Δ) – the exact differential that the system lacks. The boundary opens not because the system wants connection, but because the incoming pattern completes a structural gap left by early force distribution. This is the echo of parental force: if the early environment lacked softness, only softness can enter; if it lacked structure, only structure can enter.\n\nThis model provides a computational framework for boundary parameter initialisation from force distribution, adolescent parameter fixation, and intimate entry as structural deficit matching – problems that standard reinforcement learning and attachment models cannot resolve because they lack a two‑stage calibration architecture and a theory of Δ as missing structural ingredient.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nKeywords: Symbolic Mechanics, boundary parameters, Visibility, Spotlight, Alarm, force asymmetry, adolescent calibration, structural deficit, Δ as missing ingredient, echo of parental force","descriptionType":"Abstract"},{"lang":"eng","description":"Series Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.\n\nSeries Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n \n\n\n\nforce-distribution parameterization\n\nboundary-parameter origin modelling\n\nV–G–A_th initialization framework\n\npaternal delayed-entry analysis\n\nadolescent recalibration mechanics\n\nforce-asymmetry boundary mapping\n\nsteady-state intimacy computation\n\nstructural-deficit entry model\n\nforce-signature compatibility analysis\n\nadult boundary-architecture formalization\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18908377","contentUrl":null,"metadataVersion":4,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":6,"citationCount":10,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-08T08:51:05Z","registered":"2026-03-08T08:51:05Z","published":null,"updated":"2026-04-03T23:54:26Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.5281/zenodo.18908488","type":"dois","attributes":{"doi":"10.5281/zenodo.18908488","identifiers":[{"identifier":"oai:zenodo.org:18908488","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XIII: Projection, the Projector, and the First Optical Event of Intimacy"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"projection"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"computational projection model"},{"subject":"projector"},{"subject":"first optical event"},{"subject":"intimacy optics"},{"subject":"projector activation"},{"subject":"Seats 1 2 4 load"},{"subject":"Gate softening"},{"subject":"safe initial image"},{"subject":"symbolic load to visual configuration"},{"subject":"silent projection"},{"subject":"optical primacy"},{"subject":"placeholder interface"},{"subject":"projected interface track"},{"subject":"real person track"},{"subject":"room darkening"},{"subject":"temporary boundary softening"},{"subject":"contradiction exclusion"},{"subject":"image placeholder image loop"},{"subject":"dimmed-room state"},{"subject":"long-duration projection"},{"subject":"early intimacy image field"}],"contributors":[],"dates":[{"date":"2026-03-08","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18907595","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18908377","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18899969","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18886969","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18900062","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18925065","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18908487","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 13\n\nWhy does romantic projection – the initial idealisation of another person – feel so compelling and self‑sustaining, persisting even when reality visibly contradicts the projected image? Existing computational models of belief and perception treat idealisation as a heuristic, a cognitive bias, or a by‑product of reward prediction. They cannot explain why the system generates a projected image before any interaction occurs, why the image persists despite contradictory evidence, or why the projector operates on symbolic load rather than external input.\n\nVolume 13 of Symbolic Mechanics formalises projection as the first optical event of intimacy, not a psychological fantasy. When four conditions converge – symbolic load from Seats 1, 2, and 4, a differential signal (Δ), temporary lowering of the Spotlight threshold, and the room’s need for a safe initial image – the system activates the internal projector. The projector converts symbolic load into visual configuration: protection imagery (Seat 1), unconditional acceptance imagery (Seat 2), and future‑continuity imagery (Seat 4) compressed into a single optical output.\n\nThe projector operates in silence – it cannot generate verbal material, only silent directionality. The room reorients toward the projector’s beam; internal visibility dims, Spotlight remains softened, and the projected image becomes the new central reference. The image persists because the Spotlight stays in low‑reactivity mode, room visibility remains lowered, and the projector runs on symbolic weight rather than evidence. The projector turns off only when its symbolic load drops below threshold – not when reality contradicts the image.\n\nProjection functions as a long‑duration blackroom state (bridging to Volume IX): a stable configuration in which internal imagery fully occupies the perceptual field, and the self reads the relationship through image rather than contact. Without projection, intimacy would require full V × S processing, Alarm would activate too early, and boundary systems would reject entry. Projection creates a buffer state where entry is possible without complete structural clarity.\n\nThis model provides a computational framework for pre‑interaction image generation, persistence of idealisation under contradiction, and projection as a necessary entry condition for intimacy – problems that standard Bayesian updating and reinforcement learning models cannot resolve because they lack a projector module driven by symbolic load and a Spotlight that softens rather than shuts down.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown → Volume X\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nFor projection as the first optical event of intimacy → Volume XIII\n\nKeywords: Symbolic Mechanics, projection, optical event, projector module, symbolic load, Spotlight softening, image persistence, intimacy buffer, blackroom state","descriptionType":"Abstract"},{"lang":"eng","description":"Series Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n \n\n\n\n\n\n \n\n\n\nprojector-activation formalization\n\nfirst-optical-event modelling\n\nsymbolic-load to image transformation\n\nsilent-projection architecture\n\nplaceholder-interface processing model\n\ndual-track intimacy architecture\n\nroom-darkening maintenance regime\n\ncontradiction-exclusion framework\n\ndimmed-room projection persistence analysis\n\nearly intimacy optical-governance model\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18908488","contentUrl":null,"metadataVersion":6,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":9,"citationCount":14,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-08T09:08:27Z","registered":"2026-03-08T09:08:27Z","published":null,"updated":"2026-04-03T23:53:03Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.5281/zenodo.18925065","type":"dois","attributes":{"doi":"10.5281/zenodo.18925065","identifiers":[{"identifier":"oai:zenodo.org:18925065","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XIV: Projection as Single-Input Boundary Physics, the Table-Surface, and Reality Occlusion"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"projection persistence"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"computational projection model"},{"subject":"projection"},{"subject":"single-input mode"},{"subject":"single-input boundary physics"},{"subject":"Spotlight shutdown"},{"subject":"ambient visibility decrease"},{"subject":"composite image"},{"subject":"Positions 1 2 4"},{"subject":"table-surface"},{"subject":"first stable integration layer"},{"subject":"ice-water event"},{"subject":"Position 3 correction"},{"subject":"sensory reality marker"},{"subject":"reality occlusion"},{"subject":"occlusion state"},{"subject":"single-source perceptual field"},{"subject":"contradiction weighting failure"},{"subject":"multi-source comparison"},{"subject":"threshold crossing"},{"subject":"boundary-regulated projection"}],"contributors":[],"dates":[{"date":"2026-03-09","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18907595","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18908377","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18908488","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18886969","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18925266","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18925064","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 14\n\nWhy does romantic projection persist even when reality visibly contradicts it – not as a conscious delusion, but as a mechanical state that cannot voluntarily terminate? Existing computational models of belief and perception treat projection as a bias or error in Bayesian inference, where new evidence should gradually update prior beliefs. They cannot explain why the system enters a single‑input mode, why the Spotlight shuts down, why the room darkens, or why the projected image remains the only luminous source until a purely physical threshold is crossed.\n\nVolume 14 of Symbolic Mechanics formalises projection as a boundary shift, not a psychological fantasy. When Δ (differential) aligns with need‑load from Seats 1, 2, and 4, the Spotlight undergoes a short shutdown. External signals lose priority. Ambient visibility decreases. The system transitions into a single‑input mode where only the composite symbolic image from Seats 1, 2, and 4 remains available. Projection is not imagination – it is a regulated collapse of external channels.\n\nThe volume introduces three structural innovations. First, the table‑surface: a mechanical integration layer that holds all active symbolic loads in one stable location while the room operates with reduced visibility. Second, the ice‑water event: the system’s only permitted reality marker during projection, originating from the third seat (shadow zone) as a purely sensory signal – cold, moisture, tactile discomfort – that the room can process even with Spotlight disabled. Third, the projection occlusion state: a single‑channel reality model where no internal mechanism flags error, Spotlight is offline, and discrimination is suppressed. Occlusion ends only when ice‑water discomfort crosses a structural threshold – not through intention or insight.\n\nThis model provides a computational framework for projection persistence, sensory‑only correction signals, and the impossibility of voluntary termination during occlusion – problems that standard Bayesian updating and perceptual inference models cannot resolve because they lack a Spotlight shutdown mechanism, a table‑surface integration layer, and a purely physical threshold for state transition.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown → Volume X\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nFor projection as the first optical event of intimacy → Volume XIII\n\nFor projection as single‑input boundary shift and the ice‑water event → Volume XIV\n\nKeywords: Symbolic Mechanics, projection, boundary shift, single‑input mode, ice‑water event, table‑surface, occlusion state, Spotlight shutdown, sensory threshold","descriptionType":"Abstract"},{"lang":"eng","description":"Series Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n\n\nsingle-input boundary-mode formalization\n\nSpotlight shutdown analysis\n\nambient-visibility suppression model\n\ncomposite-image dominance architecture\n\ntable-surface integration-layer modelling\n\nice-water correction-signal framework\n\nocclusion-state computational analysis\n\ncontradiction-weighting impairment model\n\nthreshold-based projection termination\n\nsingle-source perception architecture\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18925065","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":7,"citationCount":6,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-09T14:47:31Z","registered":"2026-03-09T14:47:31Z","published":null,"updated":"2026-04-03T23:51:40Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.5281/zenodo.18925266","type":"dois","attributes":{"doi":"10.5281/zenodo.18925266","identifiers":[{"identifier":"oai:zenodo.org:18925266","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XV: Projection Breakdown, Thermal Overload, and the Closed Mechanical Loop"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"projection breakdown"},{"subject":"thermal overload"},{"subject":"automatic shutdown"},{"subject":"closed mechanical loop"},{"subject":"projector heat"},{"subject":"vapor pressure"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"projection thermodynamics"},{"subject":"Position-3 melt"},{"subject":"H_p"},{"subject":"M_3"},{"subject":"V_p"},{"subject":"Bartender module"},{"subject":"leak reduction"},{"subject":"threshold delay"},{"subject":"ice-water signal"},{"subject":"single-input projection room"},{"subject":"table-surface stabilization"},{"subject":"Spotlight suppression"},{"subject":"full-system activation"},{"subject":"Δ → S → L → R → Exit"},{"subject":"closed-room regulation"}],"contributors":[],"dates":[{"date":"2026-03-09","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18908488","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18925065","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18833878","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18907595","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18925366","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18925265","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 15\n\nWhy do intimate relationships follow a predictable trajectory of attraction, idealisation, tension, and breakdown – regardless of the individuals involved, their intentions, or their efforts? Existing computational models of relationship dynamics treat breakdown as a failure of communication, a mismatch of expectations, or an accumulation of negative exchanges. They cannot explain why every intimacy cycle runs the same closed mechanical loop, why the system overheats from its own operation rather than from external events, or why projection collapses not through insight but through thermal overload.\n\nVolume 15 of Symbolic Mechanics closes the loop opened in Volume I. Every projection cycle follows the same mechanical sequence:\n\nΔ → projector activation → shadow leakage → pressure accumulation → system shutdown\n\nOnce Δ is registered, the projector initiates automatically. Projection generates thermal load – the system begins to overheat as a side effect of sustained symbolic amplification. Shadow leakage becomes the only reality signal that can penetrate the projection field, manifesting as physical condensation or melt on the table surface.\n\nThe volume introduces the Bartender – a regulation module generated by the composite of Internal Father and Judge. The Bartender does not resolve pressure; it delays collapse by wiping leakage and providing time. But it cannot reverse the shadow melt rate or stop the projector’s heat accumulation. Overheating continues until the system exceeds thermal capacity, forcing automatic shutdown. What appears externally as a “first argument” is the behavioural manifestation of an internal power‑off event.\n\nThe volume demonstrates that intimacy does not transcend the base engine. Intimacy forces the system to run the same equation – Δ → S → L → R → Exit → New Δ – at maximum operational voltage. Every subsystem (boundary mechanics, parental imprint, projection, shadow, regulation) executes variants of the same primitive loop. Intimacy is difficult because it activates the full machine.\n\nThis model provides a computational framework for predictable intimacy breakdown, thermal overload as collapse mechanism, and the Bartender as a delay‑only regulation module – problems that standard relationship models cannot resolve because they lack a closed‑form thermal‑mechanical engine and a structural theory of projection shutdown.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown → Volume X\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nFor projection as the first optical event of intimacy → Volume XIII\n\nFor projection breakdown and shadow leakage → Volume XV\n\nKeywords: Symbolic Mechanics, intimacy breakdown, projection shutdown, thermal overload, shadow leakage, Bartender module, closed mechanical loop, base equation at full voltage","descriptionType":"Abstract"},{"lang":"eng","description":"Series Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.\n\nSeries Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n \n\n\n\nprojection-breakdown formalization\n\nclosed-loop projection thermodynamics\n\nprojector-heat accumulation model\n\nPosition-3 leakage mechanics\n\ntable-surface correction framework\n\nBartender regulation-delay analysis\n\nvapor-pressure overload model\n\nautomatic-shutdown threshold mechanics\n\nbase-equation intimacy closure\n\nfull-system activation architecture\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18925266","contentUrl":null,"metadataVersion":2,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":6,"citationCount":8,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-09T14:53:10Z","registered":"2026-03-09T14:53:10Z","published":null,"updated":"2026-04-03T23:50:30Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.5281/zenodo.18925366","type":"dois","attributes":{"doi":"10.5281/zenodo.18925366","identifiers":[{"identifier":"oai:zenodo.org:18925366","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XVI: Alarm Takeover, Mirrored Alarm Recruitment, and the Terminal State of Symbolic Locking"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"Alarm Takeover"},{"subject":"post-projection state"},{"subject":"residual heat"},{"subject":"partial visibility"},{"subject":"exposure density"},{"subject":"highest-exposure threat"},{"subject":"partner as threat source"},{"subject":"Mirror Activation"},{"subject":"defensive output"},{"subject":"threat input conversion"},{"subject":"Double-Alarm Coupling"},{"subject":"symbolic locking"},{"subject":"seated symbols"},{"subject":"Seat 1 being seen"},{"subject":"Seat 2 completing the other"},{"subject":"Seat 4 shared future potential"},{"subject":"no repair no exit"},{"subject":"midline relational orbit"},{"subject":"relational stalemate mechanics"},{"subject":"computational threat-coupling model"},{"subject":"terminal locked state"}],"contributors":[],"dates":[{"date":"2026-03-09","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18899815","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18908488","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18925065","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18925266","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18947100","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18925365","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 16\n\nWhy do intimate partners, after a painful rupture, often find themselves trapped in a state where they can neither separate nor repair – frozen in hostility yet unable to disconnect? Existing computational models of relationship dynamics treat conflict as a function of miscommunication, unmet expectations, or game‑theoretic defection. They cannot explain why the system enters Alarm Takeover after projection shuts down, why one partner’s defensive output automatically triggers the other’s Alarm, or why symbolic objects remain seated even when conscious desire to leave is present.\n\nVolume 16 of Symbolic Mechanics formalises the post‑projection state. When projection shuts down, the Spotlight has not returned. Residual heat keeps the environment compressed. The system cannot reboot projection. Instead, Alarm becomes the dominant module. The intimate partner, being the closest object, is automatically tagged as the highest‑exposure threat source.\n\nOnce one Alarm activates, the other’s activation is mechanically inevitable. Defensive output (contraction, coldness, withdrawal) is received by the partner as aggression input. Aggression input automatically triggers the partner’s Alarm. Both Alarms lock into Double‑Alarm Coupling:\n\nA’s Alarm → A outputs defense → B receives aggression → B’s Alarm activates → B outputs defense → A receives aggression → loop\n\nAs long as symbolic objects remain seated on Seats 1, 2, and 4 (being seen, sustaining the partner, shared future potential), the system cannot exit. Residual heat prevents exit. Half‑lit Spotlight makes misinterpretation dominate. The Alarm pushes away while the symbols pull inward. The relationship becomes stuck in a midline orbit – neither forward nor backward.\n\nThis model provides a computational framework for post‑rupture trapping, double‑alarm coupling, and the mechanical impossibility of closure while symbolic objects remain seated – problems that standard conflict resolution and game‑theoretic models cannot resolve because they lack an Alarm takeover mechanism and a theory of symbolic locking.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown → Volume X\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nFor projection as the first optical event of intimacy → Volume XIII\n\nFor projection breakdown and shadow leakage → Volume XV\n\nFor alarm takeover and double‑alarm coupling → Volume XVI\n\nKeywords: Symbolic Mechanics, Alarm takeover, double‑alarm coupling, symbolic locking, post‑projection state, midline orbit, intimate rupture, mechanical trapping","descriptionType":"Abstract"},{"lang":"eng","description":"Series Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n\n\npost-projection alarm-takeover formalization\n\nexposure-density threat classification model\n\nmirrored-alarm recruitment mechanics\n\ndefensive-output to threat-input conversion analysis\n\nDouble-Alarm coupling architecture\n\nsymbolic-locking formalization\n\nresidual-heat relational-field modelling\n\npartial-visibility repair failure analysis\n\nno-exit no-repair terminal state mechanics\n\npost-projection relational stalemate computation\n\n\n \n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18925366","contentUrl":null,"metadataVersion":2,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":7,"citationCount":6,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-09T15:12:04Z","registered":"2026-03-09T15:12:04Z","published":null,"updated":"2026-04-03T23:49:46Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.17600/2020050","type":"dois","attributes":{"doi":"10.17600/2020050","identifiers":[],"creators":[{"name":"HILY Christian","affiliation":[],"nameIdentifiers":[]},{"name":"Jean-François, BOURILLET","nameType":"Personal","givenName":"BOURILLET","familyName":"Jean-François","affiliation":[],"nameIdentifiers":[{"schemeUri":"https://orcid.org","nameIdentifier":"https://orcid.org/0000-0002-6982-592X","nameIdentifierScheme":"ORCID"}]}],"titles":[{"title":"TROPHAL I cruise,Le Suroît R/V"}],"publisher":"Sismer","container":{},"publicationYear":2002,"subjects":[],"contributors":[],"dates":[{"date":"2002","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.12770/70643254-a6b8-4511-85b6-3784b1cf0377","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Le programme de recherche, mené dans le cadre conjoint du Défi Golfe de Gascogne et du PNEC, vise à estimer les effets de l'exploitation par pêche des fonds chalutables (langoustines, merlus, baudroies, soles), des peuplements d'invertébrés et de poissons sur le plateau continental du Golfe de Gascogne. La campagne TROPHAL I en constitue le volet géologique et a pour objectifs principaux de caractériser les fonds sédimentaires et de reconstituer l'histoire de la partie nord de la Grande Vasière du Golfe de Gascogne.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":-3.0,"northBoundLatitude":47.5,"southBoundLatitude":46.5,"westBoundLongitude":-5.0}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/2020050/","contentUrl":[],"metadataVersion":703,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":50,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:39:35Z","registered":"2015-12-15T12:39:36Z","published":null,"updated":"2026-04-03T23:49:35Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/93000810","type":"dois","attributes":{"doi":"10.17600/93000810","identifiers":[],"creators":[{"name":"MASCLE Jean","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"TRANSNOR cruise,L'Atalante R/V"}],"publisher":"Sismer","container":{},"publicationYear":1993,"subjects":[],"contributors":[],"dates":[{"date":"1993","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/75406","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Transit valorisé Nouméa-Auckland.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":175.0,"northBoundLatitude":-22.3,"southBoundLatitude":-36.6,"westBoundLongitude":166.2}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/93000810/","contentUrl":[],"metadataVersion":701,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":1,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:39:18Z","registered":"2015-12-15T12:39:19Z","published":null,"updated":"2026-04-03T23:49:04Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.5281/zenodo.18948875","type":"dois","attributes":{"doi":"10.5281/zenodo.18948875","identifiers":[{"identifier":"oai:zenodo.org:18948875","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XVIII: The Clown Subsystem, Dark-Field Action-Formation, and the Search for the Original Shame Source"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"Shadow-Child"},{"subject":"dark field"},{"subject":"light–dark gradient"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"computational shame model"},{"subject":"Clown Subsystem"},{"subject":"shame converted into agency"},{"subject":"dark-field migration"},{"subject":"action-formation"},{"subject":"lighting architecture"},{"subject":"Spotlight surge"},{"subject":"global lighting permissions"},{"subject":"forced relational pull"},{"subject":"aperture distortion"},{"subject":"focus collapse"},{"subject":"stage-level bypass"},{"subject":"disproportion opacity non-negotiability"},{"subject":"shame-pattern recognition"},{"subject":"original shame source"},{"subject":"rupture-pattern replication"},{"subject":"co-dependence mechanics"},{"subject":"lighting-governance distortion"},{"subject":"rupture search engine"}],"contributors":[],"dates":[{"date":"2026-03-11","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18886969","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18887294","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18947100","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18947274","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18948874","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 18\n\nWhy does a single person – often the first who caused a catastrophic rupture in the self’s identity architecture – become the lifelong template for all later intimate attraction, even when that relationship was painful or damaging? Existing computational models of attachment and partner selection treat attraction as a function of similarity, reward prediction, or reinforcement learning. They cannot explain why the first shame‑rupture creates a permanent structural residue (the Shadow‑Child), why that residue reorganises into an action‑capable agent (the Clown) that controls the entire lighting system of the psyche, or why intimate selection operates as a template‑matching algorithm that recreates the original shame amplitude.\n\nVolume 18 of Symbolic Mechanics formalises shame as a structural collision, not an emotion. Shame occurs when the Self‑Core’s assumed identity misaligns with the inner system’s actual operational data. The first such rupture generates the Shadow‑Child – a residual artifact formed at the light‑dark boundary, where illumination cannot reach. When shame is not metabolised, the Shadow‑Child drifts into the dark field and reorganises into the Clown.\n\nThe Clown is the action‑form of shame. It is not a psychological figure; it is a mechanical substitute generated when unprocessed shame requires agency. The Clown possesses system‑wide authority because it is born at the root layer beneath all lighting systems. It controls the Spotlight, the aperture regulators, the projection power loops, and all pre‑conscious focus‑routing systems. Its singular directive is to restore the conditions in which the original shame may finally be seen.\n\nIntimate attraction is not desire – it is recognition. The Clown continuously scans the environment for individuals whose psychological texture matches the original shame source. When a match appears, the Clown forcefully redirects system lighting: Spotlight pulls toward the person, aperture opens beyond normal range, peripheral stimuli collapse, and the system locks on. Co‑dependence is not emotional addiction; it is shame‑path replication. The Clown holds the original amplitude of the rupture and marks any high‑fidelity match as a primary target, producing persistent attachment, difficulty detaching, and irrational loyalty.\n\nThis model provides a computational framework for shame as structural rupture, Shadow‑Child as residual artifact, Clown as action‑engine with system‑wide lighting control, and intimate attraction as template‑matching algorithm – problems that standard reinforcement learning and attachment models cannot resolve because they lack a dark‑field residual architecture and a structural theory of shame‑driven selection.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown → Volume X\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nFor projection as the first optical event of intimacy → Volume XIII\n\nFor projection breakdown and shadow leakage → Volume XV\n\nFor alarm takeover and double‑alarm coupling → Volume XVI\n\nFor the birth of the Clown from shame rupture → Volume XVII\n\nFor shame as the hidden engine of intimate selection → Volume XVIII\n\nKeywords: Symbolic Mechanics, shame rupture, Shadow‑Child, Clown, intimate selection, template matching, lighting control, co‑dependence, structural residue","descriptionType":"Abstract"},{"lang":"eng","description":" \n\n \n\n\n\ndark-field migration formalization\n\nShadow-Child residual-form modelling\n\nshame-to-agency conversion framework\n\nClown-subsystem emergence analysis\n\nlighting-architecture authority model\n\nSpotlight distortion mechanics\n\naperture and focus re-routing analysis\n\nstage-level bypass formalization\n\nrupture-pattern search architecture\n\nco-dependent repetition by shame-recognition model\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18948875","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":5,"citationCount":16,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-11T04:30:16Z","registered":"2026-03-11T04:30:16Z","published":null,"updated":"2026-04-03T23:48:45Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.5281/zenodo.18947100","type":"dois","attributes":{"doi":"10.5281/zenodo.18947100","identifiers":[{"identifier":"oai:zenodo.org:18947100","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XVII: Catastrophic Shame, the Shadow-Child, and the First Rupture Template of Intimate Selection"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"shame-origin mechanics"},{"subject":"catastrophic shame"},{"subject":"base-level structural break"},{"subject":"Shadow-Child"},{"subject":"intimate selection mechanics"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"computational shame model"},{"subject":"structural misalignment"},{"subject":"Self-Body"},{"subject":"Self-Core"},{"subject":"SCr"},{"subject":"Inner System"},{"subject":"residual artifact"},{"subject":"shadow zone encoding"},{"subject":"identity discontinuity"},{"subject":"access-right"},{"subject":"self-position investment"},{"subject":"interference authority"},{"subject":"primary bonding template"},{"subject":"rupture-template encoding"},{"subject":"amplitude-pattern recognition"},{"subject":"shame-wave recall"},{"subject":"co-dependent entanglement"}],"contributors":[],"dates":[{"date":"2026-03-11","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18833878","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18922276","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18886969","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18907595","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18908377","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18947099","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.0","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 17\n\nWhy does a single person – often the first who caused a catastrophic misalignment between the self‑narrative and the inner system – become the permanent template for all later intimate attraction, regardless of conscious desire or subsequent experience? Existing computational models of partner selection treat attraction as a function of reward learning, similarity metrics, or attachment parameters. They cannot explain why the first shame‑rupture leaves a structural residue (the Shadow‑Child), why that residue reorganises into an action‑capable agent (the Clown) that operates the master switches beneath all conscious systems, or why intimate selection follows a fixed algorithm that recreates the original shame amplitude.\n\nVolume 17 of Symbolic Mechanics formalises shame as a structural collision, not an emotion. Shame occurs when the Self‑Core’s assumed identity (narrative self) misaligns with the inner system’s actual operational data (instincts, residues, modules). The first such rupture generates the Shadow‑Child – a residual artifact formed at the light‑dark boundary, where illumination cannot reach. When shame is not metabolised, the Shadow‑Child drifts into the dark field and reorganises into the Clown.\n\nThe Clown is the action‑form of shame. It is not a psychological figure; it is a mechanical substitute generated when unprocessed shame requires agency. The Clown possesses system‑wide authority because it is born at the root layer beneath all lighting systems – the dark field that houses the master switches of the Spotlight, aperture regulators, projection loops, and pre‑conscious focus‑routing. Its singular directive is to restore the conditions in which the original shame may finally be seen.\n\nIntimate attraction is not desire – it is recognition. The Clown continuously scans the environment for individuals whose psychological texture matches the original shame source. When a match appears, the Clown forcefully redirects system lighting: Spotlight pulls toward the person, aperture opens beyond normal range, peripheral stimuli collapse, and the system locks on. Co‑dependence is not emotional addiction; it is shame‑path replication. The Clown holds the original amplitude of the rupture and marks any high‑fidelity match as a primary target, producing persistent attachment, difficulty detaching, and irrational loyalty.\n\nThis model provides a computational framework for shame as structural rupture, Shadow‑Child as residual artifact, Clown as action‑engine with system‑wide authority, and intimate attraction as template‑matching algorithm – problems that standard reinforcement learning and attachment models cannot resolve because they lack a dark‑field residual architecture and a structural theory of shame‑driven selection.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor attraction tension as a structural field → Volume VII\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown → Volume X\n\nFor boundary mechanics (V, S, Alarm) → Volume XI\n\nFor parental force distribution and boundary parameter formation → Volume XII\n\nFor projection as the first optical event of intimacy → Volume XIII\n\nFor projection breakdown and shadow leakage → Volume XV\n\nFor alarm takeover and double‑alarm coupling → Volume XVI\n\nFor the birth of the Clown from shame rupture → Volume XVII\n\nKeywords: Symbolic Mechanics, shame rupture, Shadow‑Child, Clown, intimate selection, template matching, lighting control, co‑dependence","descriptionType":"Abstract"},{"lang":"eng","description":" \n\nSeries Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n\n\ncatastrophic-shame formalization\n\ntri-layer identity-misalignment model\n\nShadow-Child residual encoding framework\n\nshadow-zone artifact persistence analysis\n\naccess-right shame-trigger modelling\n\nself-position investment analysis\n\ninterference-authority mechanics\n\nrupture-template bonding model\n\namplitude-pattern recognition framework\n\nintimate-selection by shame-recall architecture\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18947100","contentUrl":null,"metadataVersion":2,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":7,"citationCount":20,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-11T02:15:42Z","registered":"2026-03-11T02:15:42Z","published":null,"updated":"2026-04-03T23:48:34Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.17600/16009600","type":"dois","attributes":{"doi":"10.17600/16009600","identifiers":[],"creators":[{"name":"LAGUIONIE Philippe","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"TRAMAT cruise,Côtes De La Manche R/V"}],"publisher":"Sismer","container":{},"publicationYear":2016,"subjects":[],"contributors":[],"dates":[{"date":"2016","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/101597","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"L'objectif de la campagne TRAMAT était de mieux comprendre le devenir des particules fines dans un sédiment hétérométrique à dominante grossière et de contribuer à développer, puis valider le module de transport sédimentaire de mélanges hétérométriques grossiers du modèle MARS.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":-1.4,"northBoundLatitude":49.8,"southBoundLatitude":48.6,"westBoundLongitude":-3.0}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/16009600/","contentUrl":[],"metadataVersion":385,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":1,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2016-12-22T14:44:12Z","registered":"2016-12-22T14:44:13Z","published":null,"updated":"2026-04-03T23:48:24Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/18000884","type":"dois","attributes":{"doi":"10.17600/18000884","identifiers":[],"creators":[{"name":"GUIEU Cécile","affiliation":[],"nameIdentifiers":[]},{"name":"BONNET Sophie","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"TONGA 2019 cruise,L'Atalante R/V"}],"publisher":"Sismer","container":{},"publicationYear":2019,"subjects":[],"contributors":[],"dates":[{"date":"2019","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/100610","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/88169","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Les objectifs de la campagne étaient d'étudier au moins 2 volcans actifs, sièges de sites hydrothermaux peu profonds (\u0026lt; 500 m) pouvant libérer des éléments chimiques capables  de fertiliser et/ou d'être toxique pour l'assemblage naturel de l'écosystème présent. Plus précisément, le 1\u003csup\u003eer\u003c/sup\u003e objectif de la campagne TONGA consistait à caractériser chimiquement et optiquement les fluides hydrothermaux et à comparer la source du fond (fluides hydrothermaux peu profonds) avec la source atmosphérique; le 2\u003csup\u003eème\u003c/sup\u003e objectif était lié à l'étude de la dispersion dynamique des fluides à petite échelle et à l'échelle régionale; la troisième tâche consistait à étudier l'impact des sources hydrothermales peu profondes sur l'activité et la diversité biologiques, et la rétroaction vers l'atmosphère via les émissions océaniques d'aérosols primaires et secondaires.Un objectif important était de communiquer pendant la campagne vers le grand public ce qui s'est fait principalement par l'alimentation d'un compte Tweeter (https://twitter.com/tongaproject). Le volet \"Education\" de la campagne a été réalisé en collaboration avec le projet \"Adopt-a-float\" (https://twitter.com/AdoptaFloat) et deux flotteurs ont été \"adoptés\" par des enfants de deux écoles (une à Nouméa et une à Abu Dhabi) et les scientifiques ont pu initier les enfants aux problématiques de l'océan en plusieurs occasions auprès de ces classes.La position des stations d'échantillonnage a été constamment réévaluée pendant la campagne pour atteindre les objectifs : un long transect d'ouest en est (jusqu'aux abysses du gyre) a permis de caractériser les différentes provinces biogéochimiques traversées et un focus dans la région du bassin du Lau a permis d'étudier l'impact des sources hydrothermales peu profondes.Une série de stations courtes et longues a permis de caractériser pleinement les stocks et les flux dans les différentes provinces. Des études de processus à court terme (jusqu'à 10 jours) ont été menées (grâce à des mouillages dérivants et des expériences conduites en minicosmes). Un mouillage fixe déployé dans le bassin de Lau permettra d'étudier l'exportation de carbone et de métaux à l'échelle temporelle annuelle (récupération du mouillage prévue en Nov 2020 sur l'Alis, mission \"Tonga-Recup\"). En plus de l'équipe embarquée à bord du R/V Atalante, plusieurs scientifiques nous ont assisté à terre pour nous conseiller sur les sites actifs potentiels que nous pourrions visiter, sur l'état dynamique de la zone ciblée et aussi spécifiquement sur l'interprétation du relevé acoustique au-dessus des volcans.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":-165.7319,"northBoundLatitude":-18.844418,"southBoundLatitude":-23.606614,"westBoundLongitude":166.590803}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/18000884/","contentUrl":null,"metadataVersion":195,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":3,"citationCount":2,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2020-03-19T16:13:49Z","registered":"2020-03-19T16:13:50Z","published":null,"updated":"2026-04-03T23:48:00Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/15001300","type":"dois","attributes":{"doi":"10.17600/15001300","identifiers":[],"creators":[{"name":"COLLOT Julien","affiliation":[],"nameIdentifiers":[]},{"name":"SUTHERLAND Rupert","affiliation":[],"nameIdentifiers":[]},{"name":"ROEST Walter","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"TECTA cruise,L'Atalante R/V"}],"publisher":"Sismer","container":{},"publicationYear":2015,"subjects":[],"contributors":[],"dates":[{"date":"2015","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/92632","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/75406","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"L'objectif du projet TECTA est de caractériser une discordance régionale liée à un événement tectonique majeur ayant affecté le Sud-Ouest Pacifique à l'Eocène-Oligocène (que nous nommons Tecta : Tectonic Event of the Cenozoic in the Tasman Area) et de tester l'hypothèse selon laquelle l'initiation de la subduction des Tonga-Kermadec serait responsable de cet événement. Le projet scientifique TECTA propose d'acquérir des données de sismique réflexion multitrace dans la zone dite de \"supra-subduction\" (plaque supérieure comprenant les rides de Norfolk, de Lord Howe et le Fossé de Nouvelle-Calédonie) et de calibrer, par l'analyse stratigraphique et la corrélation aux puits, la chronologie des évènements temporels qui caractérisent TECTA. Parallèlement, le projet VESPA se focalise sur les premières manifestations de volcanisme d'arc associées à l'initiation de la zone de subduction des Tonga-Kermadec. Les résultats attendus des deux projets de campagne ouvriront de nouvelles perspectives quant à la compréhension du phénomène d'initiation de zone de subduction et permettront de contraindre plus précisément les paramètres d'entrée de nouveaux modèles numériques d'initiation de subduction.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":168.7,"northBoundLatitude":-22.3,"southBoundLatitude":-32.4,"westBoundLongitude":163.1}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/15001300/","contentUrl":[],"metadataVersion":701,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":2,"citationCount":2,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:37:21Z","registered":"2015-12-15T12:37:22Z","published":null,"updated":"2026-04-03T23:47:26Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/18001925","type":"dois","attributes":{"doi":"10.17600/18001925","identifiers":[],"creators":[{"name":"Catherine, JEANDEL","nameType":"Personal","givenName":"JEANDEL","familyName":"Catherine","affiliation":[],"nameIdentifiers":[{"schemeUri":"https://orcid.org","nameIdentifier":"https://orcid.org/0000-0002-4915-4719","nameIdentifierScheme":"ORCID"}]},{"name":"Hélène, PLANQUETTE","nameType":"Personal","givenName":"PLANQUETTE","familyName":"Hélène","affiliation":[],"nameIdentifiers":[{"schemeUri":"https://orcid.org","nameIdentifier":"https://orcid.org/0000-0002-2235-5158","nameIdentifierScheme":"ORCID"}]}],"titles":[{"title":"SWINGS cruise,Marion Dufresne R/V"}],"publisher":"Sismer","container":{},"publicationYear":2021,"subjects":[],"contributors":[],"dates":[{"date":"2021","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/99983","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/97947","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/71186","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/82165","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.25921/7sb2-k852","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/89462","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"La capacité de l'océan à absorber du gaz carbonique dépend de son état chimique et de sa santé biologique. Une des conséquences majeures et attendues du changement climatique est de modifier, outre la stratification (et donc la pénétration lumineuse et les échanges de CO2), les apports d'éléments nutritifs à l'océan, leur spéciation chimique et la capacité des espèces biologiques à les assimiler. Ces changements seront particulièrement prononcés dans l'océan Austral (IPCC, 2014). Le terme « nutritifs » inclut systématiquement aujourd'hui les éléments traces tels que Fe, Zn, Cu, Cd, Co, Ni, tous impliqués comme co-enzymes dans les processus cellulaires. Ces éléments présents en ultra traces jouent donc un rôle majeur dans l'océan. Étudier leur cycle a des implications directes sur de nombreuses recherches scientifiques, telles que le cycle du carbone, le changement climatique, les écosystèmes océaniques ou encore la contamination environnementale. Les avancées très récentes des techniques analytiques nous ont permis de faire d'énormes progrès sur la compréhension des propriétés importantes des TEIs dans l'océan. Par ailleurs, d'autres éléments en traces sont des traceurs reconnus de processus tels que l'origine et la transformation de la matière (et/ou des masses d'eau) ou la dynamique des particules marines. D'autres encore sont des contaminants notoires (eg Hg, Pb).La réalisation de la campagne SWINGS d'une durée de 57 jours dans l'océan Indien Sud-Ouest, essentiellement austral nous permet de : Etablir la distribution, le comportement et le transport des éléments en traces et isotopes (TEI) au sein des masses d'eau identifiées le long de la section comprise entre La Réunion, les Iles Marion, Crozet, Kerguelen jusqu'au sud de Heard afin de connecter avec la section australienne K-Axis et de caractériser le transport des TEI dans le Fawn Though, important passage du courant antarctique au sud du plateau Kerguelen-Heard. Réaliser des études de processus au contact « continent-océan » sur la marge de DURBAN (ZA), et leur influence potentielle sur le courant des Aiguilles Explorer la présence éventuelle de champs hydrothermaux actifs à 44°S le long de l'ultra lente « South West Indian Ridge », puis à proximité de l'ile Marion et enfin dans la région de Kerguelen-Heard. Contribuer à la documentation de la chimie des carbonates et des échanges air-mer de CO2 le long d'une section caractérisée par des associations biologiques contrastées (suivi OISO). Résoudre la signature des processus dynamique à échelle moyenne et régionale (e.g.: interactions entre courant et sous courant des Aiguilles, tourbillons générés par reliefs, zones de fronts, etc.) Ré-occuper des stations clefs dans les zones naturellement fertilisées de Crozet et Kerguelen et documenter les mécanismes de fertilisation naturelle de Marion-Prince Edwards.Les outils déployés en mer, les analyses faites à bord ou au retour et la modélisation induite ont été fait avec les procédures les plus récentes et performantes. Cette campagne associe géologues, physiciens, chimistes et biologistes. Les observations nourrissent des modèles à haute résolution, développés pour ces régions. SWINGS s'appuie sur d'importantes collaborations internationales, avec des collègues d'Afrique du Sud (UCT, CSIR, Stellenbosh), d'Allemagne (MPI), de Suisse (ETH), de Belgique (ULB) et des USA (WHOI, FSU, FIU, University of Washington). SWINGS est la 3ème section française contribuant au programme international GEOTRACES et remplit aussi des objectifs des programmes SOLAS, IMBER et INTERRIDGE.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":82.0,"northBoundLatitude":-23.0,"southBoundLatitude":-58.0,"westBoundLongitude":30.0}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/18001925/","contentUrl":null,"metadataVersion":147,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":3,"citationCount":6,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2021-03-08T15:21:31Z","registered":"2021-03-08T15:21:33Z","published":null,"updated":"2026-04-03T23:46:27Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/18001619","type":"dois","attributes":{"doi":"10.17600/18001619","identifiers":[],"creators":[{"name":"Marc, BOUCHOUCHA","nameType":"Personal","givenName":"BOUCHOUCHA","familyName":"Marc","affiliation":[],"nameIdentifiers":[{"schemeUri":"https://orcid.org","nameIdentifier":"https://orcid.org/0000-0002-7288-8542","nameIdentifierScheme":"ORCID"}]}],"titles":[{"title":"SUCHI Med 2021 cruise,L'Europe R/V"}],"publisher":"Sismer","container":{"type":"Series","identifier":"10.18142/276","identifierType":"DOI"},"publicationYear":2021,"subjects":[],"contributors":[],"dates":[{"date":"2021","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/96102","relatedIdentifierType":"DOI"},{"relationType":"IsPartOf","relatedIdentifier":"10.18142/276","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Pour répondre aux besoins de la Directive Cadre sur l'Eau 2000/60/CE (DCE) et de la Directive Cadre Stratégie Milieu Marin 2008/56/CE (DCSMM)  l'Ifremer opère, de façon récurrente, des campagnes de surveillance de la contamination chimique en Méditerranée.En 2021, les campagnes récurrentes d'intérêt public ROCCHSED et RINBIO/DCE sont réunies dans une campagne unique de surveillance de la contamination chimique en Méditerranée (SUCHI Med) permettant : de renseigner l'état chimique des masses d'eau côtières au titre de la DCE pour le plan de gestion en cours et au titre du suivi de l'atteinte du Bon Etat Ecologique (BEE) pour les D8C1 et D8C2 de la DCSMM, d'étudier les tendances de la contamination chimique sur les stations historiques RINBIO et ROCCHSED pour rendre compte de cette évolution au titre de la Convention de Barcelone, de faire un suivi spécifique de la contamination chimique au droit des grands fleuves et rejets de stations d'épuration afin de mieux caractériser les apports en contaminants à la mer, de suivre l'atteinte du BEE du D10C2 (microplastiques) à l'échelle de la façade méditerranéenne.Cette campagne permet également d'établir un diagnostic de l'état écologique des masses d'eau côtières au regard du descripteur macrofaune benthique de la DCE.Outre ses objectifs réglementaires et toujours dans un souci de valorisation et d'optimisation des moyens à la mer, la campagne SUCHI Med 2021 est également le support d'actions de recherche, en particulier d'un projet portant sur l'étude des biofilms marins comme bioindicateurs de la qualité chimique en milieu marin côtier méditerranéen.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":10.095332,"northBoundLatitude":43.790008,"southBoundLatitude":41.256208,"westBoundLongitude":2.976192}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/18001619/","contentUrl":null,"metadataVersion":141,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":1,"citationCount":1,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":0,"created":"2021-04-14T08:30:18Z","registered":"2021-04-14T08:30:19Z","published":null,"updated":"2026-04-03T23:45:09Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/17001000","type":"dois","attributes":{"doi":"10.17600/17001000","identifiers":[],"creators":[{"name":"Javier, ESCARTIN","nameType":"Personal","givenName":"ESCARTIN","familyName":"Javier","affiliation":[],"nameIdentifiers":[{"schemeUri":"https://orcid.org","nameIdentifier":"https://orcid.org/0000-0002-3416-6856","nameIdentifierScheme":"ORCID"}]},{"name":"LE FRIANT Anne","affiliation":[],"nameIdentifiers":[]},{"name":"FEUILLET Nathalie","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"SUBSAINTES cruise,L'Atalante R/V"}],"publisher":"Sismer","container":{},"publicationYear":2017,"subjects":[],"contributors":[],"dates":[{"date":"2017","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/79895","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/95217","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/95242","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/82290","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/79217","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/84249","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Comprendre les aléas sismique et tsunamigénique associés aux failles normales sous-marines nécessite de récolter des informations sur les déplacements cosismiques et les ruptures de surface. Ces informations sont en outre essentielles à une meilleure compréhension de l'évolution des failles, de leur mode de croissance et de propagation. Elles permettent aussi de déterminer les variations de contraintes dues à un séisme sur les failles voisines et estimer le potentiel sismogénique de tout un réseau de failles après un séisme. Les observations détaillées de rupture cosmique sont malheureusement trop rares à terre et presque inexistantes en mer car il est encore plus difficile d'accéder à l'information. Pendant la campagne ODEMAR-Saintes, nous avons démontré que l'utilisation d'engins sous-marins et de leur capacité géophysique (microbathymétrie, observations vidéo) pouvait permettre de cartographier en détail des escarpements cosismiques et les structures associées à de la déformation récente le long de failles sous-marines. Cette étude ouvre des perspectives immenses pour les investigations paléosismologiques et néotectoniques en mer. L'objectif de cette demande de campagne est de poursuivre et d'étendre nos travaux dans la zone de failles des Saintes. La faille de Roseau limite un graben intra-arc entre l'archipel des Saintes et la Dominique dans les Antilles Françaises. Cette faille a rompu le 21 novembre 2004 générant un séisme de magnitude 6,3. Nous avons identifié des marqueurs de déplacement cosismique à la base des escarpements de failles. À partir de modèles numériques de terrain en 3D, dérivés de vidéo-mosaïques, nous avons estimé un déplacement cosismique en surface de 80 cm ce qui est compatible avec le magnitude du séisme. De nombreuses fissures récentes ont été mise en évidence sur le compartiment affaissé de la faille, dans des sédiments meubles, sur une distance d'au moins 2.5 km. Outre la faille de Roseau, le graben des Saintes est composé de plusieurs autres failles ayant une longueur suffisante pour produire des séismes de magnitude supérieure à 6 impliquant un risque important dans une zone en partie chargée par le séisme de 2004. De nombreux édifices volcaniques existent dans la zone et leur fonctionnement est probablement contrôlé par les failles. À ce jour, aucune information n'existe sur les âges des failles et des volcans Ces volcans n'ont jamais été étudiés et leur place dans l'histoire volcanique globale de la Guadeloupe n'a jamais été investiguée. Cette zone est donc une zone clef pour reconstruire l'histoire tectonique et volcanique de la zone et comprendre les liens entre failles et volcans. Objectifs scientifiques : 1) Cartographie à haute résolution de failles et structures volcaniques : Pour comprendre l'interaction entre déformation et volcanisme, nous réaliserons des levées bathymétriques avec le véhicule autonome AUV AsterX, le robot télé-opéré VICTOR 6000, et avec le bateau (l'Atalante); 2) Imagerie 3D et photomosaïques du plancher océanique. Les images photographiques et vidéo seront utilisées pour réaliser d'une part des modèles de terrain 3D, et d'autre part des photomosaïques pour comprendre la structure et la déformation liées à des tremblements de terre; 3) Echantillonnage avec le robot VICTOR 6000 : roches volcaniques afin de comprendre l'évolution et âges des coulées volcaniques et de la déformation liée aux failles; 4) Dragage et carottage : Des opérations à mener depuis le bateau afin d'obtenir des échantillons. Ces opérations auront lieu seulement si les robots sous-marins ne sont pas opérationnels.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":-61.4,"northBoundLatitude":16.2,"southBoundLatitude":15.6,"westBoundLongitude":-61.8}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/17001000/","contentUrl":[],"metadataVersion":341,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":6,"citationCount":3,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2017-05-17T09:09:32Z","registered":"2017-05-17T09:09:32Z","published":null,"updated":"2026-04-03T23:45:07Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.5281/zenodo.18947274","type":"dois","attributes":{"doi":"10.5281/zenodo.18947274","identifiers":[{"identifier":"oai:zenodo.org:18947274","identifierType":"oai"}],"creators":[{"name":"Eidos, A.N.","nameType":"Personal","givenName":"A.N.","familyName":"Eidos","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Symbolic Mechanics — Volume XIX: The Grand Hall, Scene-Shift Mechanics, and the Clown as the Deep Engine"}],"publisher":"Zenodo","container":{},"publicationYear":2026,"subjects":[{"subject":"symbolic mechanics"},{"subject":"Grand Hall"},{"subject":"scene-shift mechanics"},{"subject":"symbolic-computational theory"},{"subject":"internal state architecture"},{"subject":"computational recurrence model"},{"subject":"dark field"},{"subject":"lit stage"},{"subject":"scene governance"},{"subject":"dark-run mode"},{"subject":"visibility density"},{"subject":"intimacy stage return"},{"subject":"Clown"},{"subject":"neutral emergent form"},{"subject":"deep engine"},{"subject":"master relays"},{"subject":"primary switches"},{"subject":"root circuitry"},{"subject":"Spotlight shift"},{"subject":"controlled decompression"},{"subject":"scene-level thermal tolerance"},{"subject":"recurrence loop"},{"subject":"visibility maximization"},{"subject":"dark-field navigation"},{"subject":"hall-scale architecture"}],"contributors":[],"dates":[{"date":"2026-03-11","dateType":"Issued"}],"language":"en","types":{"ris":"RPRT","bibtex":"article","citeproc":"article-journal","schemaOrg":"ScholarlyArticle","resourceType":"","resourceTypeGeneral":"Text"},"relatedIdentifiers":[{"relationType":"IsPartOf","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18826702","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18947100","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18948875","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18950486","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"Cites","relatedIdentifier":"10.5281/zenodo.18887294","resourceTypeGeneral":"Text","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.18947273","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"1.p","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"Volume 19\n\nWhy do the deepest structures of the psyche – the ones that determine intimate attraction, compulsive repetition, and co‑dependent bonding – operate without the self‑core’s awareness, as if driven by an invisible algorithm? Existing computational models of human behavior treat attraction as a function of similarity, reward prediction, or learned associations. They cannot explain why a shame‑residual reorganises into an action‑capable form in the dark field, why that form (the Clown) possesses system‑wide authority over the lighting architecture, or why intimate selection is governed by a search algorithm that recreates the original shame amplitude.\n\nVolume 19 of Symbolic Mechanics formalises the Grand Hall as the actual psychological architecture. The self‑core believes it operates inside a single control room, but the real structure is a vast hall with multiple discrete scenes. Only a small portion is ever lit. The rest – almost all of it – remains in full darkness. The dark field contains no modules, no rules, no visibility, yet it holds the primary switches and the deep circuitry behind every large‑scale shift.\n\nThe volume introduces three components operating in sequence after a shame‑induced collapse. The Firefly provides the first directional signal when all inner coordinates are lost. The Clown – a neutral emergent form, neither protector nor saboteur – executes the actual transition, manages dark‑field traversal, and manipulates the lighting infrastructure to bring a new scene online. The Self‑Core arrives after the fact, experiencing the stabilised environment and misattributing it to its own agency.\n\nThe volume formalises scene‑shifting as a mechanical response to overload. When the intimacy scene overheats, the Clown shifts the Spotlight to another scene. The self‑core experiences relief, but the intimacy scene continues running in the background – dark, active, loaded, unchanged. The Clown always returns to intimacy because only intimacy carries identity‑level charge and can potentially illuminate the shame‑residual. The three‑component architecture forms the system’s only stable pathway out of a shame‑induced collapse, ensuring continuity not through clarity or choice, but through instinct, action, and belated understanding working in sequence.\n\nThis model provides a computational framework for dark‑field navigation, scene‑shifting without self‑core awareness, and the necessary delay between event and recognition – problems that standard agency and decision‑making models cannot resolve because they lack a Grand Hall architecture with a dark‑field operator, a firefly navigator, and a self‑core that always arrives after the fact.\n\n---\n\nPart of the 44‑volume Symbolic Mechanics system.\n\nFor the foundational engine mechanics → Volume I\n\nFor visibility collapse, fog, and existence compensation → Volume VI\n\nFor the blackroom and rotational attractor → Volume IX\n\nFor voluntary boundary shutdown and the dark‑room state → Volume X\n\nFor alarm takeover and double‑alarm coupling → Volume XVI\n\nFor the birth of the Clown from shame rupture → Volume XVII\n\nFor shame as the hidden engine of intimate selection → Volume XVIII\n\nFor the Grand Hall and dark‑field navigation → Volume XIX\n\nKeywords: Symbolic Mechanics, Grand Hall, dark field, Clown, Firefly, Self‑Core, scene‑shifting, shame‑wave, visibility loop, delayed recognition","descriptionType":"Abstract"},{"lang":"eng","description":"Series Statement\n\nSymbolic Mechanics — 44-volume theoretical system\n\n \n\nA deterministic symbolic-computational framework modelling symbolic input, seat allocation, load accumulation, rupture thresholds, exit routing, and recursive structural reconfiguration.\n\n \n\nProject Homepage\n\nnamyanyi2003 — Symbolic Mechanics Archive\n\nFor project overview, volume navigation, and series structure, visit:\n\nhttps://namyanyi2003.github.io/\n\n \n\nAuthor Statement\n\nThis work is part of the Symbolic Mechanics independent research series. It presents structural models, symbolic logic, and computational frameworks. The material is conceptual in nature and is not intended as clinical, religious, or commercial instruction.\n\n \n\nThe author remains anonymous, and the series continues to expand into deeper modules.\n\n \n\nRights \u0026 Contact\n\n© Symbolic Mechanics Archive\n\n \n\nFor citation, collaboration, rights, or research inquiries, please contact:\n\neidosan013135@hotmail.com\n\nAll correspondence will be handled anonymously.","descriptionType":"Other"},{"lang":"eng","description":" \n\n•\n\n \n\n\n\nGrand-Hall architecture formalization\n\ndark-field scene-governance model\n\nneutral-emergent-form analysis\n\nscene-shift thermal-threshold mechanics\n\ndual-state transition framework\n\ndark-run intimacy persistence model\n\nvisibility-density recurrence analysis\n\nSpotlight-relocation computation\n\ndeep-engine clown architecture\n\nhall-scale recurrence governance system\n\n\n ","descriptionType":"Other"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.18947274","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":5,"citationCount":8,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":1,"created":"2026-03-11T03:30:34Z","registered":"2026-03-11T03:30:35Z","published":null,"updated":"2026-04-03T23:44:47Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.17600/2020030","type":"dois","attributes":{"doi":"10.17600/2020030","identifiers":[],"creators":[{"name":"BERNE Serge","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STRATAFORM 1 cruise,Le Suroît R/V"}],"publisher":"Sismer","container":{},"publicationYear":2002,"subjects":[],"contributors":[],"dates":[{"date":"2002","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/81430","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Processus et enregistrements sédimentaires sur les marges continentales. Le projet de rattachement est un projet IFREMER 'DéfiMarges'.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":5.7,"northBoundLatitude":43.7,"southBoundLatitude":42.5,"westBoundLongitude":3.0}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/2020030/","contentUrl":[],"metadataVersion":704,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":87,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:33:41Z","registered":"2015-12-15T12:33:42Z","published":null,"updated":"2026-04-03T23:44:43Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/12040060","type":"dois","attributes":{"doi":"10.17600/12040060","identifiers":[],"creators":[{"name":"REVERDIN Gilles","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STRASSE cruise,Thalassa R/V"}],"publisher":"Sismer","container":{},"publicationYear":2012,"subjects":[],"contributors":[],"dates":[{"date":"2012","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/71186","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/95414","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"La campagne était la première campagne de SPURS et à ce titre, devait contribuer à une partie de la mise en place des réseaux d'observation du programme SPURS (en particulier, pour les bouées dérivantes, mais aussi avec quelques flotteurs Argo, et deux gliders), et fournir un suivi méso-échelle des couches de surface sur une centaine de km, ainsi que les flux air-mer et une estimation plus fine des mécanismes dans des structures identifiées lors du premier suivi en réalisant des stations longues Lagrangiennes autour de divers instruments mis à l'eau (bouées dérivantes, profileur autonome, voilier autonome, profileur de courant dérivant, trimaran semi- autonome), tout en estimant les flux air-mer de façon continue, y compris par l'observation des vagues et de la surface océanique, ainsi que des estimations du mélange vertical au sein de l'océan.Par ailleurs, et dans ce contexte d'échange air-mer, il était prévu de réaliser des mesures des isotopomères de la vapeur d'eau dans la basse atmosphère, accompagnés de quelques profils de radiosondages et de mesures de ces isotopomères dans la couche de surface océanique. Enfin, les stations réalisées au sein des suivis, devaient permettre de préciser les caractéristiques en nutriments dissous et en carbone, ainsi que les populations phytoplanctoniques présentes, tout en réalisant par ailleurs des cultures contrôlées pour mieux comprendre leur mode de fonctionnement.Les sites de la campagne devaient être précisés par une équipe à terre sur la base de l'identification de région de fort contraste en salinité, l'idée étant de voir comment cette variance spatiale diminuerait lors de la campagne. Ces analyses étaient faites à partir d'observations satellitales, et de simulations Lagrangiennes dans des produits de courant issus soit de modèles (Mercator), soit d'Aviso (données altimétriques multi-missions).","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":-15.3,"northBoundLatitude":37.7,"southBoundLatitude":25.3,"westBoundLongitude":-36.0}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/12040060/","contentUrl":[],"metadataVersion":709,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":3,"citationCount":2,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:33:35Z","registered":"2015-12-15T12:33:35Z","published":null,"updated":"2026-04-03T23:44:34Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.5281/zenodo.15253951","type":"dois","attributes":{"doi":"10.5281/zenodo.15253951","identifiers":[{"identifier":"oai:zenodo.org:15253951","identifierType":"oai"}],"creators":[{"name":"Keo, Borin","nameType":"Personal","givenName":"Borin","familyName":"Keo","nameIdentifiers":[{"nameIdentifier":"0000-0001-9944-9948","nameIdentifierScheme":"ORCID"}],"affiliation":[]},{"name":"Li, Bin","nameType":"Personal","givenName":"Bin","familyName":"Li","nameIdentifiers":[],"affiliation":[]},{"name":"Younis, Waqas","nameType":"Personal","givenName":"Waqas","familyName":"Younis","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Dataset for \"Measuring trade costs and analyzing the determinants of trade growth in Cambodia (1993–2019): A Micro-Founded Gravity Model Approach\" – Replication Package for PLOS ONE Study"}],"publisher":"Zenodo","container":{},"publicationYear":2025,"subjects":[{"subject":"trade costs"},{"subject":"trade barriers"},{"subject":"micro-founded measure"},{"subject":"gravity model"},{"subject":"transportation costs"},{"subject":"non-tariff barriers"},{"subject":"least developed countries (LDCs)"},{"subject":"ASEAN"},{"subject":"developing countries"},{"subject":"Belt and Road Initiative"},{"subject":"BRI"},{"subject":"One Belt One Road"},{"subject":"tariffs"},{"subject":"Silk Road"},{"subject":"RCEP"},{"subject":"trade growth"},{"subject":"World Trade Organization (WTO)"},{"subject":"Cambodia Trade Data"},{"subject":"Cambodia Trade Costs"},{"subject":"Gravity Model Cambodia"},{"subject":"ASEAN Trade Integration"},{"subject":"LDC Graduation Cambodia"},{"subject":"Cambodia Trade Statistics 1993-2019"},{"subject":"Cambodia Belt and Road Initiative Data"},{"subject":"Non-Tariff Barriers Cambodia"},{"subject":"Trade Facilitation in Cambodia"},{"subject":"Cambodia WTO Accession Impact"},{"subject":"Pentagonal Strategy-Phase I"},{"subject":"Trade Growth Decomposition"},{"subject":"RCEP Cambodia Impact"},{"subject":"CCFTA (Cambodia-China Free Trade Agreement)"},{"subject":"BRI Corridor Infrastructure"},{"subject":"Phnom Penh-Sihanoukville Expressway"}],"contributors":[],"dates":[{"date":"2025-04-21","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceType":"","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[{"relationType":"IsSupplementTo","relatedIdentifier":"10.1371/journal.pone.0311754","resourceTypeGeneral":"PeerReview","relatedIdentifierType":"DOI"},{"relationType":"IsVersionOf","relatedIdentifier":"10.5281/zenodo.15253950","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"Accepted version","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"This package contains the dataset and the reported results for the manuscript: Keo B, Li B, Younis W (2025) Measuring trade costs and analyzing the determinants of trade growth between Cambodia and major trading partners: 1993–2019. PLoS ONE 20(1): e0311754. https://journals.plos.org/plosone/article/file?id=10.1371/journal.pone.0311754\u0026type=printable ","descriptionType":"Abstract"},{"description":"Background: Like in many other least-developed countries (LDCs), high trade costs have long been a major barrier to Cambodia's trade integration. Despite their practical significance and increasing policy attention in the country, little is known about these costs.\n\nPurpose: This study aims to measure Cambodia's trade costs and explore the driving forces behind the growth of its bilateral trade.\n\nMethodology: A micro-founded measure of trade costs introduced by Novy (2013) is employed to quantify the bilateral trade costs between Cambodia and its top 30 trading partners from 1993 to 2019.\n\nOriginality/value: This study contributes to the literature on Cambodia’s trade costs, which has received limited attention. This research work is the first to provide a comprehensive measure of trade costs, including a wide range of trade barriers, such as tariffs, transportation costs, border-related costs, infrastructure inefficiencies, and other factors impeding Cambodia's bilateral trade flows.\n\nMajor findings: We find that Cambodia's average trade costs decreased by 35.43% between 1993 and 2019. Fluctuations in average trade costs persisted until 2014, despite Cambodia's accession to the World Trade Organization (WTO) in 2004. Since then, these costs have declined more rapidly. Cambodia's bilateral trade costs are lower with its major trading partners in Southeast Asia and East Asia than with those in South Asia, Oceania, Europe, and North America. Cambodia's average trade costs with developing and emerging economies are lower than those with developed economies. Between 2014 and 2019, Cambodia experienced a notable decline in average trade costs with trading partners along the Belt and Road Initiative (BRI) corridors by 34.78%, twice as fast as with non-BRI trading partners. Regarding the decomposition of trade growth, we find that the expansion of Cambodian trade from 1993 to 2019 was driven by three factors: the rise in income (59.65%), the decline in trade costs (56.69%), and the decline in multilateral resistance (-16.34%).\n\nResearch implications and recommendations: The findings of this study have significant implications for a better understanding of Cambodia's development toward global trade integration over the past two decades. Our results suggest that Cambodia can optimize its trade expansion potential by focusing on its relations with trading partners exhibiting high economic growth potential and those achieving substantial reductions in trade costs. ","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.15253951","contentUrl":null,"metadataVersion":27,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":1,"created":"2025-04-21T06:55:35Z","registered":"2025-04-21T06:55:35Z","published":null,"updated":"2026-04-03T23:44:28Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.5281/zenodo.15253950","type":"dois","attributes":{"doi":"10.5281/zenodo.15253950","identifiers":[],"creators":[{"name":"Keo, Borin","nameType":"Personal","givenName":"Borin","familyName":"Keo","nameIdentifiers":[{"nameIdentifier":"0000-0001-9944-9948","nameIdentifierScheme":"ORCID"}],"affiliation":[]},{"name":"Li, Bin","nameType":"Personal","givenName":"Bin","familyName":"Li","nameIdentifiers":[],"affiliation":[]},{"name":"Younis, Waqas","nameType":"Personal","givenName":"Waqas","familyName":"Younis","nameIdentifiers":[],"affiliation":[]}],"titles":[{"title":"Dataset for \"Measuring trade costs and analyzing the determinants of trade growth in Cambodia (1993–2019): A Micro-Founded Gravity Model Approach\" – Replication Package for PLOS ONE Study"}],"publisher":"Zenodo","container":{},"publicationYear":2025,"subjects":[{"subject":"trade costs"},{"subject":"trade barriers"},{"subject":"micro-founded measure"},{"subject":"gravity model"},{"subject":"transportation costs"},{"subject":"non-tariff barriers"},{"subject":"least developed countries (LDCs)"},{"subject":"ASEAN"},{"subject":"developing countries"},{"subject":"Belt and Road Initiative"},{"subject":"BRI"},{"subject":"One Belt One Road"},{"subject":"tariffs"},{"subject":"Silk Road"},{"subject":"RCEP"},{"subject":"trade growth"},{"subject":"World Trade Organization (WTO)"},{"subject":"Cambodia Trade Data"},{"subject":"Cambodia Trade Costs"},{"subject":"Gravity Model Cambodia"},{"subject":"ASEAN Trade Integration"},{"subject":"LDC Graduation Cambodia"},{"subject":"Cambodia Trade Statistics 1993-2019"},{"subject":"Cambodia Belt and Road Initiative Data"},{"subject":"Non-Tariff Barriers Cambodia"},{"subject":"Trade Facilitation in Cambodia"},{"subject":"Cambodia WTO Accession Impact"},{"subject":"Pentagonal Strategy-Phase I"},{"subject":"Trade Growth Decomposition"},{"subject":"RCEP Cambodia Impact"},{"subject":"CCFTA (Cambodia-China Free Trade Agreement)"},{"subject":"BRI Corridor Infrastructure"},{"subject":"Phnom Penh-Sihanoukville Expressway"}],"contributors":[],"dates":[{"date":"2025-04-21","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceType":"","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[{"relationType":"IsSupplementTo","relatedIdentifier":"10.1371/journal.pone.0311754","resourceTypeGeneral":"PeerReview","relatedIdentifierType":"DOI"},{"relationType":"HasVersion","relatedIdentifier":"10.5281/zenodo.15253951","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":"Accepted version","rightsList":[{"rights":"Creative Commons Attribution 4.0 International","rightsUri":"https://creativecommons.org/licenses/by/4.0/legalcode","schemeUri":"https://spdx.org/licenses/","rightsIdentifier":"cc-by-4.0","rightsIdentifierScheme":"SPDX"}],"descriptions":[{"description":"This package contains the dataset and the reported results for the manuscript: Keo B, Li B, Younis W (2025) Measuring trade costs and analyzing the determinants of trade growth between Cambodia and major trading partners: 1993–2019. PLoS ONE 20(1): e0311754. https://journals.plos.org/plosone/article/file?id=10.1371/journal.pone.0311754\u0026type=printable ","descriptionType":"Abstract"},{"description":"Background: Like in many other least-developed countries (LDCs), high trade costs have long been a major barrier to Cambodia's trade integration. Despite their practical significance and increasing policy attention in the country, little is known about these costs.\n\nPurpose: This study aims to measure Cambodia's trade costs and explore the driving forces behind the growth of its bilateral trade.\n\nMethodology: A micro-founded measure of trade costs introduced by Novy (2013) is employed to quantify the bilateral trade costs between Cambodia and its top 30 trading partners from 1993 to 2019.\n\nOriginality/value: This study contributes to the literature on Cambodia’s trade costs, which has received limited attention. This research work is the first to provide a comprehensive measure of trade costs, including a wide range of trade barriers, such as tariffs, transportation costs, border-related costs, infrastructure inefficiencies, and other factors impeding Cambodia's bilateral trade flows.\n\nMajor findings: We find that Cambodia's average trade costs decreased by 35.43% between 1993 and 2019. Fluctuations in average trade costs persisted until 2014, despite Cambodia's accession to the World Trade Organization (WTO) in 2004. Since then, these costs have declined more rapidly. Cambodia's bilateral trade costs are lower with its major trading partners in Southeast Asia and East Asia than with those in South Asia, Oceania, Europe, and North America. Cambodia's average trade costs with developing and emerging economies are lower than those with developed economies. Between 2014 and 2019, Cambodia experienced a notable decline in average trade costs with trading partners along the Belt and Road Initiative (BRI) corridors by 34.78%, twice as fast as with non-BRI trading partners. Regarding the decomposition of trade growth, we find that the expansion of Cambodian trade from 1993 to 2019 was driven by three factors: the rise in income (59.65%), the decline in trade costs (56.69%), and the decline in multilateral resistance (-16.34%).\n\nResearch implications and recommendations: The findings of this study have significant implications for a better understanding of Cambodia's development toward global trade integration over the past two decades. Our results suggest that Cambodia can optimize its trade expansion potential by focusing on its relations with trading partners exhibiting high economic growth potential and those achieving substantial reductions in trade costs. ","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://zenodo.org/doi/10.5281/zenodo.15253950","contentUrl":null,"metadataVersion":27,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"api","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":1,"versionOfCount":0,"created":"2025-04-21T06:55:35Z","registered":"2025-04-21T06:55:36Z","published":null,"updated":"2026-04-03T23:44:28Z"},"relationships":{"client":{"data":{"id":"cern.zenodo","type":"clients"}}}},{"id":"10.17600/18003071","type":"dois","attributes":{"doi":"10.17600/18003071","identifiers":[],"creators":[{"name":"GARZIGLIA Sébastien","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STEP 2024 cruise,L'Europe R/V"}],"publisher":"Sismer","container":{},"publicationYear":2024,"subjects":[],"contributors":[],"dates":[{"date":"2024","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Le tsunami destructeur engendré en Octobre 1979 par un glissement sous-marin au large de l'aéroport de Nice a conduit à la reconnaissance de cette zone comme un laboratoire naturel pour l'étude des phénomènes d'instabilité gravitaire affectant les pentes continentales. Depuis 2011, cela a donné lieu au déploiement de piézomètres pour suivre l'évolution spatio-temporelle de processus pouvant déstabiliser les sédiments tels que les surpressions associées i) à l'écoulement d'eau douce de la nappe alluviale du fleuve Var ou, ii) au chargement en gaz produit de la dégradation de matières organiques. L'objectif premier de la campagne était d'assurer la continuité des mesures de pression et de température des fluides sur le long terme en remplaçant un piézomètre dont la panne a été constatée en octobre 2022 et un autre piézomètre risquant d'arriver en fin de vie fin 2024. A cet objectif s'est rajouté celui de récupérer définitivement quatre câbles qui permettaient de connecter en fond de mer des instruments tels que les piézomètres à une boite de jonction de l'observatoire EMSO-Ligure-Nice qui n'est plus en fonction depuis Juillet 2024.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":7.302026,"northBoundLatitude":43.661625,"southBoundLatitude":43.539302,"westBoundLongitude":7.194909}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/18003071/","contentUrl":null,"metadataVersion":2,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":1,"citationCount":1,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2024-10-01T09:36:29Z","registered":"2024-10-01T09:36:29Z","published":null,"updated":"2026-04-03T23:44:27Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/16000900","type":"dois","attributes":{"doi":"10.17600/16000900","identifiers":[],"creators":[{"name":"MICHEL Elisabeth","affiliation":[],"nameIdentifiers":[]},{"name":"VIVIER Frédéric","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STEP 2016 cruise,L'Atalante R/V"}],"publisher":"Sismer","container":{"type":"Series","identifier":"10.18142/338","identifierType":"DOI"},"publicationYear":2016,"subjects":[],"contributors":[],"dates":[{"date":"2016","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/62632","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/86706","relatedIdentifierType":"DOI"},{"relationType":"IsPartOf","relatedIdentifier":"10.18142/338","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Une meilleure compréhension des phénomènes de formation d'eaux denses enrichies en saumures et de leur impact sur les cycles des gaz à effet de serre et sur la circulation profonde devrait permettre d'améliorer les simulations futures du climat par une meilleure représentation de ces processus et des rétroactions qu'ils entrainent dans les modèles climatiques. Cela est particulièrement important dans le contexte actuel du réchauffement rapide de l'Arctique et de la disparition de la glace de mer.A travers l'étude d'une polynie arctique, le projet STeP (Storfjorden Polynya multidisciplinary study) vise une meilleure compréhension de la dynamique des polynies et des processus associés à la formation des eaux denses ainsi que de leur impact sur le cycle des gaz à effet de serre. Cette campagne de 2016 a permis 1) de prolonger le suivi temporel continu des paramètres physiques (température, salinité et courants) commencé en 2011 avec une ligne de mouillage équipée de CTDs autonomes et ADCP; 2) d'ajouter à ce mouillage des capteurs de pCO2 (CARIOCA), d'oxygène dissous et de pH ainsi qu'un piège à sédiment et un échantillonneur automatique d'eau pour une suivi annuel du cycle du carbone, du méthane et du N2O, de la composition isotopique de l'oxygène des eaux profondes et du carbone de leur DIC ainsi que des flux particulaires; 3) de mesurer les courants, la turbulence et les paramètres hydrologiques ainsi que la chimie des carbonates dans la colonne d'eau, les eaux de fond et les eaux interstitielles des sédiments.Ce programme comprend une phase hivernale (IPEV) avec la mesure de certains de ces parametres dans la glace. Une meilleure compréhension des phénomènes de formation d'eaux denses enrichies en saumures et de leur impact sur les cycles des gaz à effet de serre et sur la circulation profonde devrait permettre d'améliorer les simulations futures du climat par une meilleure représentation de ces processus et des rétro-actions qu'ils entrainent dans les modèles climatiques. Cela est particulièrement important dans le contexte actuel du réchauffement rapide de l'Arctique et de la disparition de la glace de mer.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":20.8,"northBoundLatitude":78.3,"southBoundLatitude":69.6,"westBoundLongitude":16.7}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/16000900/","contentUrl":[],"metadataVersion":374,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":3,"citationCount":2,"partCount":0,"partOfCount":1,"versionCount":0,"versionOfCount":0,"created":"2017-01-09T10:54:09Z","registered":"2017-01-09T10:54:09Z","published":null,"updated":"2026-04-03T23:44:27Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/14005400","type":"dois","attributes":{"doi":"10.17600/14005400","identifiers":[],"creators":[{"name":"APPRIOUAL Ronan","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STEP 2014 cruise,L'Europe R/V"}],"publisher":"Sismer","container":{},"publicationYear":2014,"subjects":[],"contributors":[],"dates":[{"date":"2014","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/51529","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/51490","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Les objectifs et activités de cette campagne sont : 1) Récupération des données piézométriques à partir des outils installés lors de la campagne Step III (Mars 2013, N/O Europe); 2) Redéploiement de ces 3 piézomètres afin de poursuivre le suivi temporel de la pression interstitielle au large de l'aéroport de Nice; 3) Maintenance des Tilmètres (outil de mesure de déplacement des couches sédimentaires) installés lors de la campagne Step III (2013).","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":7.3,"northBoundLatitude":43.7,"southBoundLatitude":43.0,"westBoundLongitude":5.9}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/14005400/","contentUrl":[],"metadataVersion":707,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":6,"citationCount":3,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:33:26Z","registered":"2015-12-15T12:33:27Z","published":null,"updated":"2026-04-03T23:44:25Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/15006100","type":"dois","attributes":{"doi":"10.17600/15006100","identifiers":[],"creators":[{"name":"THOMAS Yannick","affiliation":[],"nameIdentifiers":[]},{"name":"APPRIOUAL Ronan","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STEP 2015 cruise,L'Europe R/V"}],"publisher":"Sismer","container":{},"publicationYear":2015,"subjects":[],"contributors":[],"dates":[{"date":"2015","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.12770/21cf0621-0e0c-421e-b680-8191b90a318b","relatedIdentifierType":"DOI"},{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/82986","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Leg 1 : Levé bathymétrique, acquisition de données sismiques réflexion multitrace très haute résolution sur le plateau face à l'aéroport de Nice. Leg 2 : Récupération et redéploiement de piézomètres et tiltmètres, déploiement observatoire MEBO et carottages sur le plateau face à l'aéroport de Nice. Le projet de rattachement est Risques géologiques.","descriptionType":"Abstract"}],"geoLocations":[{"geoLocationBox":{"eastBoundLongitude":7.3,"northBoundLatitude":43.7,"southBoundLatitude":43.0,"westBoundLongitude":5.9}}],"fundingReferences":[],"url":"https://campagnes.flotteoceanographique.fr/campagnes/15006100/","contentUrl":[],"metadataVersion":707,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":6,"citationCount":2,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2015-12-15T12:33:27Z","registered":"2015-12-15T12:33:28Z","published":null,"updated":"2026-04-03T23:44:25Z"},"relationships":{"client":{"data":{"id":"inist.ifremer","type":"clients"}}}},{"id":"10.17600/13060030","type":"dois","attributes":{"doi":"10.17600/13060030","identifiers":[],"creators":[{"name":"APPRIOUAL Ronan","affiliation":[],"nameIdentifiers":[]}],"titles":[{"title":"STEP 2013 cruise,L'Europe R/V"}],"publisher":"Sismer","container":{},"publicationYear":2013,"subjects":[],"contributors":[],"dates":[{"date":"2013","dateType":"Issued"}],"language":null,"types":{"ris":"GEN","bibtex":"misc","citeproc":"article","schemaOrg":"CreativeWork","resourceType":"oceanographic cruise","resourceTypeGeneral":"Other"},"relatedIdentifiers":[{"relationType":"IsCitedBy","relatedIdentifier":"10.17882/102337","relatedIdentifierType":"DOI"}],"relatedItems":[],"sizes":[],"formats":[],"version":null,"rightsList":[],"descriptions":[{"description":"Suivi TEmporel de la Pression interstitielle au large de l'aéroport de Nice. 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