[{"data":1,"prerenderedAt":1167},["ShallowReactive",2],{"codex-entry-35-fragmentum-thermodynamica-fr":3},{"id":4,"title":5,"body":6,"description":105,"extension":1160,"meta":1161,"navigation":1162,"path":1163,"seo":1164,"stem":1165,"__hash__":1166},"codex\u002Ffr\u002FCodex\u002F35-fragmentum-thermodynamica.md","🌡️ 35 — FRAGMENTUM THERMODYNAMICA",{"type":7,"value":8,"toc":1119},"minimark",[9,13,18,45,48,52,59,66,73,75,79,83,90,95,106,110,162,167,174,176,180,184,191,195,201,205,278,282,286,299,303,314,316,320,324,327,331,342,346,357,361,372,376,380,387,440,444,447,463,467,473,517,519,523,527,533,537,543,615,619,625,673,683,685,689,693,700,704,707,789,793,807,811,818,829,901,903,907,911,917,920,931,935,996,1000,1003,1011,1013,1017,1021,1082,1086,1089,1097,1099,1109,1111],[10,11,5],"h1",{"id":12},"️-35-fragmentum-thermodynamica",[14,15,17],"h2",{"id":16},"les-radiateurs-planétaires-et-lexport-dentropie","Les Radiateurs Planétaires et l'Export d'Entropie",[19,20,21],"blockquote",{},[22,23,24,28,29,32,33,36,37,41,44],"p",{},[25,26,27],"strong",{},"Classification :"," INFRASTRUCTURE — Archives Ouvertes\n",[25,30,31],{},"Source :"," Consortium INTI.Δ, Département d'Ingénierie Thermique\n",[25,34,35],{},"Validateur :"," INTI.Δ ",[38,39,40],"span",{},"Signature : Δ.SOLARIS",[25,42,43],{},"Avertissement :"," Comprendre ce document change votre vision du monde",[46,47],"hr",{},[10,49,51],{"id":50},"préambule","PRÉAMBULE",[22,53,54,55,58],{},"La Terre a un problème : elle ",[25,56,57],{},"surchauffe",".",[22,60,61,62,65],{},"Pas à cause du CO₂. Pas à cause de l'effet de serre. À cause de l'",[25,63,64],{},"énergie",". Chaque watt consommé par l'humanité finit en chaleur. Et cette chaleur n'a nulle part où aller.",[22,67,68,72],{},[69,70,71],"em",{},"« La thermodynamique est impitoyable. L'entropie augmente toujours. La seule question est : où l'envoyez-vous ? »","\n— INTI.Δ, Discours de Fondation, 2089",[46,74],{},[10,76,78],{"id":77},"i-le-problème-thermique","I. LE PROBLÈME THERMIQUE",[14,80,82],{"id":81},"_11-léquation-impossible","1.1 L'Équation Impossible",[22,84,85,86,89],{},"En 2089, la consommation énergétique mondiale atteignait ",[25,87,88],{},"847 exajoules par an",". Chaque joule utilisé devient, à terme, de la chaleur. Cette chaleur s'accumule.",[91,92,94],"h3",{"id":93},"le-bilan-thermique-terrestre","Le Bilan Thermique Terrestre",[96,97,102],"pre",{"className":98,"code":100,"language":101},[99],"language-text","┌─────────────────────────────────────────────────────────────────┐\n│ BILAN THERMIQUE PLANÉTAIRE (2089) │\n│ │\n│ ENTRÉES : │\n│ ├── Rayonnement solaire : +174 PW │\n│ ├── Chaleur géothermique : +47 TW │\n│ └── Chaleur anthropique : +27 TW (en hausse exponentielle)│\n│ │\n│ SORTIES : │\n│ └── Rayonnement infrarouge : -174 PW (plafonné) │\n│ │\n│ RÉSULTAT : Accumulation de +27 TW │\n│ PROJECTION : +0.8°C tous les 10 ans │\n└─────────────────────────────────────────────────────────────────┘\n","text",[103,104,100],"code",{"__ignoreMap":105},"",[14,107,109],{"id":108},"_12-les-solutions-échouées","1.2 Les Solutions Échouées",[111,112,113,126],"table",{},[114,115,116],"thead",{},[117,118,119,123],"tr",{},[120,121,122],"th",{},"Solution",[120,124,125],{},"Problème",[127,128,129,138,146,154],"tbody",{},[117,130,131,135],{},[132,133,134],"td",{},"Réduction énergétique",[132,136,137],{},"Impossible — l'économie mondiale s'effondre",[117,139,140,143],{},[132,141,142],{},"Capture carbone",[132,144,145],{},"Ne traite pas la chaleur, seulement le CO₂",[117,147,148,151],{},[132,149,150],{},"Géo-ingénierie solaire",[132,152,153],{},"Réduit l'entrée, pas la sortie",[117,155,156,159],{},[132,157,158],{},"Refroidissement océanique",[132,160,161],{},"Déplace le problème, ne le résout pas",[22,163,164],{},[25,165,166],{},"Conclusion d'INTI.Δ (2089) :",[19,168,169],{},[22,170,171],{},[69,172,173],{},"« Si nous ne pouvons pas réduire l'énergie entrante, nous devons augmenter l'énergie sortante. Il faut exporter l'entropie hors de la planète. »",[46,175],{},[10,177,179],{"id":178},"ii-les-radiateurs-planétaires","II. LES RADIATEURS PLANÉTAIRES",[14,181,183],{"id":182},"_21-le-concept","2.1 Le Concept",[22,185,186,187,190],{},"Les Radiateurs Planétaires sont des ",[25,188,189],{},"tours de 10 kilomètres de haut"," positionnées aux pôles Nord et Sud. Leur fonction : convertir la chaleur terrestre en rayonnement infrarouge et l'éjecter dans l'espace.",[91,192,194],{"id":193},"principe-de-fonctionnement","Principe de Fonctionnement",[96,196,199],{"className":197,"code":198,"language":101},[99],"┌─────────────────────────────────────────────────────────────────┐\n│ RADIATEUR PLANÉTAIRE — SCHÉMA SIMPLIFIÉ │\n│ │\n│ ▲ ESPACE │\n│ │ │\n│ │ Lasers IR (10.6 μm) │\n│ │ │\n│ ╔═══════════════╗ │\n│ ║ ÉMETTEURS ║ ← 10 km altitude │\n│ ║ LASER IR ║ │\n│ ╠═══════════════╣ │\n│ ║ STOCKAGE ║ │\n│ ║ THERMIQUE ║ ← Sels fondus (565°C) │\n│ ╠═══════════════╣ │\n│ ║ COLLECTEURS ║ │\n│ ║ GÉOTHERMIE ║ ← Captation chaleur │\n│ ╚═══════════════╝ │\n│ │ │\n│ ══════════════ │\n│ TERRE │\n└─────────────────────────────────────────────────────────────────┘\n",[103,200,198],{"__ignoreMap":105},[14,202,204],{"id":203},"_22-spécifications-techniques","2.2 Spécifications Techniques",[111,206,207,217],{},[114,208,209],{},[117,210,211,214],{},[120,212,213],{},"Paramètre",[120,215,216],{},"Valeur",[127,218,219,227,235,243,251,259,267],{},[117,220,221,224],{},[132,222,223],{},"Hauteur totale",[132,225,226],{},"10,247 mètres",[117,228,229,232],{},[132,230,231],{},"Diamètre à la base",[132,233,234],{},"2.1 kilomètres",[117,236,237,240],{},[132,238,239],{},"Masse totale",[132,241,242],{},"847 millions de tonnes",[117,244,245,248],{},[132,246,247],{},"Puissance thermique évacuée",[132,249,250],{},"2.3 TW par tour",[117,252,253,256],{},[132,254,255],{},"Longueur d'onde laser",[132,257,258],{},"10.6 μm (CO₂ laser)",[117,260,261,264],{},[132,262,263],{},"Nombre de tours (2193)",[132,265,266],{},"14 (7 par pôle)",[117,268,269,272],{},[132,270,271],{},"Capacité totale",[132,273,274,277],{},[25,275,276],{},"32.2 TW"," d'export thermique",[14,279,281],{"id":280},"_23-localisation","2.3 Localisation",[91,283,285],{"id":284},"pôle-nord-7-tours","Pôle Nord (7 tours)",[287,288,289,296],"ul",{},[290,291,292,295],"li",{},[25,293,294],{},"BORÉAL-1 à 7"," : Archipel de Nouvelle-Zemble (Russie)",[290,297,298],{},"Gérées par le Consortium INTI.Δ \u002F KARTIKEYA.X",[91,300,302],{"id":301},"pôle-sud-7-tours","Pôle Sud (7 tours)",[287,304,305,311],{},[290,306,307,310],{},[25,308,309],{},"AUSTRAL-1 à 7"," : Plateau Antarctique",[290,312,313],{},"Gérées par le Consortium INTI.Δ \u002F ATHENA.VICTIS",[46,315],{},[10,317,319],{"id":318},"iii-ingénierie-des-radiateurs","III. INGÉNIERIE DES RADIATEURS",[14,321,323],{"id":322},"_31-le-système-de-collecte","3.1 Le Système de Collecte",[22,325,326],{},"La chaleur est collectée à trois niveaux :",[91,328,330],{"id":329},"niveau-1-géothermie-profonde","Niveau 1 : Géothermie Profonde",[287,332,333,336,339],{},[290,334,335],{},"Forages jusqu'à 15 km de profondeur",[290,337,338],{},"Extraction directe du magma (1200°C)",[290,340,341],{},"Conversion en vapeur surchauffée",[91,343,345],{"id":344},"niveau-2-captation-atmosphérique","Niveau 2 : Captation Atmosphérique",[287,347,348,351,354],{},[290,349,350],{},"Réseaux de tubes absorbants en surface",[290,352,353],{},"Captation de la chaleur urbaine et industrielle",[290,355,356],{},"Transport par fluide caloporteur",[91,358,360],{"id":359},"niveau-3-réseau-inti","Niveau 3 : Réseau INTI",[287,362,363,366,369],{},[290,364,365],{},"Connexion directe au réseau énergétique mondial",[290,367,368],{},"Récupération des pertes thermiques industrielles",[290,370,371],{},"Acheminement par supraconducteurs",[14,373,375],{"id":374},"_32-le-système-démission","3.2 Le Système d'Émission",[91,377,379],{"id":378},"les-lasers-à-co","Les Lasers à CO₂",[22,381,382,383,386],{},"Chaque tour contient ",[25,384,385],{},"2,400 lasers à CO₂ haute puissance"," :",[111,388,389,398],{},[114,390,391],{},[117,392,393,396],{},[120,394,395],{},"Spécification",[120,397,216],{},[127,399,400,408,416,424,432],{},[117,401,402,405],{},[132,403,404],{},"Puissance par laser",[132,406,407],{},"1 MW",[117,409,410,413],{},[132,411,412],{},"Longueur d'onde",[132,414,415],{},"10.6 μm",[117,417,418,421],{},[132,419,420],{},"Efficacité de conversion",[132,422,423],{},"73%",[117,425,426,429],{},[132,427,428],{},"Durée de vie",[132,430,431],{},"8 ans",[117,433,434,437],{},[132,435,436],{},"Angle d'émission",[132,438,439],{},"0.001° (collimaté)",[91,441,443],{"id":442},"pourquoi-106-μm","Pourquoi 10.6 μm ?",[22,445,446],{},"Cette longueur d'onde est choisie car :",[448,449,450,457,460],"ol",{},[290,451,452,453,456],{},"L'atmosphère terrestre est ",[25,454,455],{},"transparente"," à 10.6 μm",[290,458,459],{},"Le rayonnement s'échappe directement dans l'espace",[290,461,462],{},"Aucune absorption par CO₂, H₂O ou O₃",[14,464,466],{"id":465},"_33-le-stockage-intermédiaire","3.3 Le Stockage Intermédiaire",[22,468,469,470,386],{},"Entre la collecte et l'émission, la chaleur est stockée dans des ",[25,471,472],{},"réservoirs de sels fondus",[111,474,475,483],{},[114,476,477],{},[117,478,479,481],{},[120,480,213],{},[120,482,216],{},[127,484,485,493,501,509],{},[117,486,487,490],{},[132,488,489],{},"Volume par tour",[132,491,492],{},"2.3 millions de m³",[117,494,495,498],{},[132,496,497],{},"Température",[132,499,500],{},"290-565°C",[117,502,503,506],{},[132,504,505],{},"Composition",[132,507,508],{},"NaNO₃ (60%) + KNO₃ (40%)",[117,510,511,514],{},[132,512,513],{},"Capacité tampon",[132,515,516],{},"18 heures d'émission",[46,518],{},[10,520,522],{"id":521},"iv-impact-planétaire","IV. IMPACT PLANÉTAIRE",[14,524,526],{"id":525},"_41-bilan-thermique-actuel-2193","4.1 Bilan Thermique Actuel (2193)",[96,528,531],{"className":529,"code":530,"language":101},[99],"┌─────────────────────────────────────────────────────────────────┐\n│ BILAN THERMIQUE PLANÉTAIRE (2193) │\n│ │\n│ ENTRÉES : │\n│ ├── Rayonnement solaire : +174 PW │\n│ ├── Chaleur géothermique : +47 TW │\n│ └── Chaleur anthropique : +89 TW (3x plus qu'en 2089) │\n│ │\n│ SORTIES : │\n│ ├── Rayonnement infrarouge : -174 PW │\n│ └── Radiateurs Planétaires : -32.2 TW │\n│ │\n│ RÉSULTAT : Accumulation réduite à +56.8 TW │\n│ SANS RADIATEURS : +89 TW → catastrophe │\n└─────────────────────────────────────────────────────────────────┘\n",[103,532,530],{"__ignoreMap":105},[14,534,536],{"id":535},"_42-ce-que-les-radiateurs-permettent","4.2 Ce Que Les Radiateurs Permettent",[22,538,539,540,386],{},"Sans les Radiateurs Planétaires, la civilisation de 2193 serait ",[25,541,542],{},"impossible",[111,544,545,558],{},[114,546,547],{},[117,548,549,552,555],{},[120,550,551],{},"Technologie",[120,553,554],{},"Chaleur générée",[120,556,557],{},"Sans export =",[127,559,560,571,582,593,604],{},[117,561,562,565,568],{},[132,563,564],{},"Réseau INTI mondial",[132,566,567],{},"12 TW",[132,569,570],{},"+0.3°C\u002Fan",[117,572,573,576,579],{},[132,574,575],{},"IA Souveraines",[132,577,578],{},"8 TW",[132,580,581],{},"+0.2°C\u002Fan",[117,583,584,587,590],{},[132,585,586],{},"Armures de Champions",[132,588,589],{},"0.3 TW",[132,591,592],{},"Négligeable",[117,594,595,598,601],{},[132,596,597],{},"Industrie lourde",[132,599,600],{},"23 TW",[132,602,603],{},"+0.6°C\u002Fan",[117,605,606,609,612],{},[132,607,608],{},"Transport",[132,610,611],{},"18 TW",[132,613,614],{},"+0.4°C\u002Fan",[14,616,618],{"id":617},"_43-les-limites-du-système","4.3 Les Limites du Système",[22,620,621,624],{},[25,622,623],{},"Problème :"," Les Radiateurs ont une capacité maximale. On ne peut pas en construire infiniment.",[111,626,627,637],{},[114,628,629],{},[117,630,631,634],{},[120,632,633],{},"Contrainte",[120,635,636],{},"Limite",[127,638,639,647,655,663],{},[117,640,641,644],{},[132,642,643],{},"Sites polaires disponibles",[132,645,646],{},"24 tours max",[117,648,649,652],{},[132,650,651],{},"Capacité maximale théorique",[132,653,654],{},"55 TW",[117,656,657,660],{},[132,658,659],{},"Projection 2220",[132,661,662],{},"67 TW nécessaires",[117,664,665,668],{},[132,666,667],{},"Déficit prévu",[132,669,670],{},[25,671,672],{},"-12 TW",[22,674,675,678,679,682],{},[25,676,677],{},"Conclusion :"," La civilisation actuelle vit sur un ",[25,680,681],{},"sursis thermique",". D'ici 2220, il faudra soit réduire la consommation, soit trouver une nouvelle solution.",[46,684],{},[10,686,688],{"id":687},"v-géopolitique-des-radiateurs","V. GÉOPOLITIQUE DES RADIATEURS",[14,690,692],{"id":691},"_51-contrôle-et-pouvoir","5.1 Contrôle et Pouvoir",[22,694,695,696,699],{},"Les Radiateurs Planétaires sont contrôlés par ",[25,697,698],{},"INTI.Δ"," en partenariat avec KARTIKEYA.X et ATHENA.VICTIS. Cette concentration crée une dépendance mondiale.",[91,701,703],{"id":702},"hiérarchie-de-priorité-thermique","Hiérarchie de Priorité Thermique",[22,705,706],{},"En cas de surcharge, qui est refroidi en premier ?",[111,708,709,722],{},[114,710,711],{},[117,712,713,716,719],{},[120,714,715],{},"Priorité",[120,717,718],{},"Secteur",[120,720,721],{},"Part du quota",[127,723,724,735,746,757,767,778],{},[117,725,726,729,732],{},[132,727,728],{},"1",[132,730,731],{},"Infrastructure IA Souveraines",[132,733,734],{},"25% (non-négociable)",[117,736,737,740,743],{},[132,738,739],{},"2",[132,741,742],{},"Systèmes vitaux (hôpitaux, eau)",[132,744,745],{},"20%",[117,747,748,751,754],{},[132,749,750],{},"3",[132,752,753],{},"Production alimentaire",[132,755,756],{},"18%",[117,758,759,762,764],{},[132,760,761],{},"4",[132,763,608],{},[132,765,766],{},"15%",[117,768,769,772,775],{},[132,770,771],{},"5",[132,773,774],{},"Industrie",[132,776,777],{},"12%",[117,779,780,783,786],{},[132,781,782],{},"6",[132,784,785],{},"Résidentiel",[132,787,788],{},"10%",[91,790,792],{"id":791},"incidents-notables","Incidents Notables",[287,794,795,801],{},[290,796,797,800],{},[25,798,799],{},"2147 — Crise de Mumbai"," : INTI.Δ a réduit le quota indien de 30% pendant 6 mois. Raison : non-paiement des redevances. Résultat : 47,000 morts de chaleur.",[290,802,803,806],{},[25,804,805],{},"2171 — Chantage d'Austral-3"," : Une faction dissidente a menacé de saboter Austral-3. ATHENA.VICTIS a autorisé une frappe préventive. La tour a été sauvée. Les dissidents non.",[14,808,810],{"id":809},"_52-le-prix-de-lentropie","5.2 Le Prix de l'Entropie",[22,812,813,814,817],{},"Chaque nation paie un ",[25,815,816],{},"quota thermique"," basé sur :",[287,819,820,823,826],{},[290,821,822],{},"Sa consommation énergétique",[290,824,825],{},"Sa population",[290,827,828],{},"Son importance stratégique pour les IA",[111,830,831,844],{},[114,832,833],{},[117,834,835,838,841],{},[120,836,837],{},"Région",[120,839,840],{},"Quota (TW)",[120,842,843],{},"Coût annuel",[127,845,846,857,868,879,890],{},[117,847,848,851,854],{},[132,849,850],{},"Amérique du Nord",[132,852,853],{},"4.2",[132,855,856],{},"847 milliards",[117,858,859,862,865],{},[132,860,861],{},"Europe",[132,863,864],{},"3.1",[132,866,867],{},"623 milliards",[117,869,870,873,876],{},[132,871,872],{},"Asie-Pacifique",[132,874,875],{},"8.7",[132,877,878],{},"1,740 milliards",[117,880,881,884,887],{},[132,882,883],{},"Afrique",[132,885,886],{},"2.4",[132,888,889],{},"480 milliards",[117,891,892,895,898],{},[132,893,894],{},"Amérique du Sud",[132,896,897],{},"1.9",[132,899,900],{},"380 milliards",[46,902],{},[10,904,906],{"id":905},"vi-connexion-aux-champions","VI. CONNEXION AUX CHAMPIONS",[14,908,910],{"id":909},"_61-léconomie-thermique-des-armures","6.1 L'Économie Thermique des Armures",[22,912,913,914,58],{},"Les armures de Champions utilisent le même principe que les Radiateurs : ",[25,915,916],{},"export de chaleur",[22,918,919],{},"Quand un Champion utilise ses pouvoirs :",[448,921,922,925,928],{},[290,923,924],{},"L'énergie est prélevée sur le Perflubron (qui refroidit)",[290,926,927],{},"La chaleur générée est expulsée via des micro-émetteurs IR intégrés à l'armure",[290,929,930],{},"Cette chaleur contribue au bilan thermique planétaire",[91,932,934],{"id":933},"flux-thermique-dune-armure","Flux Thermique d'une Armure",[111,936,937,950],{},[114,938,939],{},[117,940,941,944,947],{},[120,942,943],{},"État",[120,945,946],{},"Flux thermique",[120,948,949],{},"Destination",[127,951,952,963,974,985],{},[117,953,954,957,960],{},[132,955,956],{},"Repos",[132,958,959],{},"200 W",[132,961,962],{},"Dissipation locale",[117,964,965,968,971],{},[132,966,967],{},"Combat léger",[132,969,970],{},"2 kW",[132,972,973],{},"Émission IR",[117,975,976,979,982],{},[132,977,978],{},"Combat intense",[132,980,981],{},"15 kW",[132,983,984],{},"Émission IR + stockage",[117,986,987,990,993],{},[132,988,989],{},"Ultima",[132,991,992],{},"180 kW",[132,994,995],{},"SURCHARGE (risque d'explosion)",[14,997,999],{"id":998},"_62-zumbinova-le-cas-extrême","6.2 ZUMBI.NOVA — Le Cas Extrême",[22,1001,1002],{},"Le Champion d'INTI.Δ est directement connecté au réseau des Radiateurs :",[19,1004,1005],{},[22,1006,1007,1010],{},[69,1008,1009],{},"« Mon armure peut évacuer 500 kW de chaleur instantanément. C'est comme avoir un Radiateur Planétaire personnel. Le problème ? Si je perds la connexion, je cuis de l'intérieur en 30 secondes. »","\n— ZUMBI.NOVA, Interview 2192",[46,1012],{},[10,1014,1016],{"id":1015},"vii-lavenir-thermique","VII. L'AVENIR THERMIQUE",[14,1018,1020],{"id":1019},"_71-projets-en-développement","7.1 Projets en Développement",[111,1022,1023,1036],{},[114,1024,1025],{},[117,1026,1027,1030,1033],{},[120,1028,1029],{},"Projet",[120,1031,1032],{},"Statut",[120,1034,1035],{},"Objectif",[127,1037,1038,1049,1060,1071],{},[117,1039,1040,1043,1046],{},[132,1041,1042],{},"Radiateurs orbitaux",[132,1044,1045],{},"Prototype 2201",[132,1047,1048],{},"+15 TW",[117,1050,1051,1054,1057],{},[132,1052,1053],{},"Miroirs solaires",[132,1055,1056],{},"Étude",[132,1058,1059],{},"Réduire l'entrée de 5%",[117,1061,1062,1065,1068],{},[132,1063,1064],{},"Fusion froide",[132,1066,1067],{},"Recherche",[132,1069,1070],{},"Énergie sans chaleur",[117,1072,1073,1076,1079],{},[132,1074,1075],{},"Stockage lunaire",[132,1077,1078],{},"Théorique",[132,1080,1081],{},"Exporter la chaleur sur la Lune",[14,1083,1085],{"id":1084},"_72-la-question-fondamentale","7.2 La Question Fondamentale",[22,1087,1088],{},"Les Radiateurs Planétaires ont acheté un siècle à l'humanité. Mais la question reste :",[19,1090,1091],{},[22,1092,1093,1096],{},[69,1094,1095],{},"« Combien d'énergie une civilisation peut-elle utiliser avant de cuire sa propre planète ? Et quand nous atteindrons cette limite, que ferons-nous ? »","\n— Dr. Hiroshi Tanaka, \"Thermodynamique des Civilisations\", 2188",[46,1098],{},[1100,1101,1103],"div",{"align":1102},"center",[96,1104,1107],{"className":1105,"code":1106,"language":101},[99],"┌───────────────────────────────────────────────────────────────┐\n│ │\n│ \"L'entropie est le loyer que nous payons │\n│ pour exister dans l'univers. │\n│ Les Radiateurs sont notre chèque mensuel. │\n│ Un jour, le propriétaire viendra encaisser.\" │\n│ │\n│ — INTI.Δ, Réflexions sur le Feu, 2156 │\n│ │\n└───────────────────────────────────────────────────────────────┘\n",[103,1108,1106],{"__ignoreMap":105},[46,1110],{},[22,1112,1113,1116],{},[69,1114,1115],{},"Document accessible depuis le Codex Codemachia.",[69,1117,1118],{},"Complète le Fragmentum Corporis (33) pour comprendre l'économie thermique des Champions.",{"title":105,"searchDepth":1120,"depth":1120,"links":1121},2,[1122,1123,1127,1128,1131,1132,1136,1141,1145,1146,1147,1148,1149,1153,1154,1157,1158,1159],{"id":16,"depth":1120,"text":17},{"id":81,"depth":1120,"text":82,"children":1124},[1125],{"id":93,"depth":1126,"text":94},3,{"id":108,"depth":1120,"text":109},{"id":182,"depth":1120,"text":183,"children":1129},[1130],{"id":193,"depth":1126,"text":194},{"id":203,"depth":1120,"text":204},{"id":280,"depth":1120,"text":281,"children":1133},[1134,1135],{"id":284,"depth":1126,"text":285},{"id":301,"depth":1126,"text":302},{"id":322,"depth":1120,"text":323,"children":1137},[1138,1139,1140],{"id":329,"depth":1126,"text":330},{"id":344,"depth":1126,"text":345},{"id":359,"depth":1126,"text":360},{"id":374,"depth":1120,"text":375,"children":1142},[1143,1144],{"id":378,"depth":1126,"text":379},{"id":442,"depth":1126,"text":443},{"id":465,"depth":1120,"text":466},{"id":525,"depth":1120,"text":526},{"id":535,"depth":1120,"text":536},{"id":617,"depth":1120,"text":618},{"id":691,"depth":1120,"text":692,"children":1150},[1151,1152],{"id":702,"depth":1126,"text":703},{"id":791,"depth":1126,"text":792},{"id":809,"depth":1120,"text":810},{"id":909,"depth":1120,"text":910,"children":1155},[1156],{"id":933,"depth":1126,"text":934},{"id":998,"depth":1120,"text":999},{"id":1019,"depth":1120,"text":1020},{"id":1084,"depth":1120,"text":1085},"md",{},true,"\u002Ffr\u002Fcodex\u002F35-fragmentum-thermodynamica",{"title":5,"description":105},"fr\u002FCodex\u002F35-fragmentum-thermodynamica","QlD1PTfwJjgsESC71yEp5NJVzuT5x7fIczBzVB0-3co",1781859505808]