. . . "10"^^ . "1123887514"^^ . . . "O diamante \u00E9 um cristal sob uma forma alotr\u00F3pica do carbono, de f\u00F3rmula qu\u00EDmica C. \u00C9 a forma triangular est\u00E1vel do carbono em press\u00F5es acima de 6 GPa (60 kbar). Comercializados como pedras preciosas, os diamantes possuem um alto valor agregado. Normalmente, o diamante cristaliza com estrutura c\u00FAbica e pode ser sintetizado industrialmente. Outra forma de cristaliza\u00E7\u00E3o do diamante \u00E9 a hexagonal, menos comum na natureza e com dureza menor (9,5 na escala de Mohs). A caracter\u00EDstica que difere os diamantes de outras formas alotr\u00F3picas, \u00E9 o fato de cada \u00E1tomo de carbono estar hibridizado em sp\u00B3, e encontrar-se ligado a outros 4 \u00E1tomos de carbono por meio de liga\u00E7\u00F5es covalentes em um arranjo tridimensional tetra\u00E9drico. O diamante pode ser convertido em grafite, o al\u00F3tropo termodinamicamente est\u00E1ve"@pt . . . . . . "129121"^^ . . . . . "\u0623\u0644\u0645\u0627\u0633"@ar . . . . "Diamond"@en . . . "Diamanto"@eo . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "no"@en . . . . . . "Transparent to subtransparent to translucent"@en . . "Irregular/Uneven"@en . . . . . . "( \uB2E4\uB978 \uB73B\uC5D0 \uB300\uD574\uC11C\uB294 \uB2E4\uC774\uC544\uBAAC\uB4DC (\uB3D9\uC74C\uC774\uC758) \uBB38\uC11C\uB97C \uCC38\uACE0\uD558\uC2ED\uC2DC\uC624.) \uB2E4\uC774\uC544\uBAAC\uB4DC(\uC601\uC5B4: diamond) \uB610\uB294 \uAE08\uAC15\uC11D(\u91D1\u525B\u77F3)\uC740 \uCC9C\uC5F0\uAD11\uBB3C\uC911 \uAC00\uC7A5 \uAD73\uAE30\uAC00 \uC6B0\uC218\uD558\uBA70 \uAD11\uCC44\uAC00 \uB6F0\uC5B4\uB09C \uBCF4\uC11D\uC774\uB2E4. \uC8FC\uC131\uBD84\uC740 \uD0C4\uC18C\uC774\uBA70 \uBD84\uC790\uAD6C\uC870\uC0C1\uC758 \uCC28\uC774\uB85C \uC778\uD574 \uB3D9\uC77C\uD55C \uC6D0\uC790\uB85C \uAD6C\uC131\uB41C \uC790\uC5F0 \uC0B0\uBB3C\uC778 \uD751\uC5F0\uACFC\uB294 \uB9E4\uC6B0 \uB2E4\uB978 \uD2B9\uC131\uC744 \uAC00\uC9C4 \uBCF4\uC11D\uC774\uB2E4. \uB6F0\uC5B4\uB09C \uACBD\uB3C4\uB85C \uC778\uD574 \uACF5\uC5C5\uC6A9\uC73C\uB85C\uB3C4 \uB9CE\uC774 \uC4F0\uC774\uB098, \uB300\uBD80\uBD84\uC758 \uACF5\uC5C5\uC6A9 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uC778\uAC04\uC774 \uB9CC\uB4E0 \uC778\uC870 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB97C \uC4F4\uB2E4. \uD604\uC7AC\uC5D0 \uC774\uB974\uB7EC\uC11C\uB294 \uC9C8\uC774 \uB098\uC05C \uC790\uC5F0 \uB2E4\uC774\uC544\uBAAC\uB4DC\uC640 \uC9C8\uC774 \uC88B\uC740 \uACF5\uC5C5\uC6A9 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB97C \uC2DD\uBCC4\uD558\uAE30 \uC5B4\uB835\uB2E4. \uD754\uD788 \uB2E4\uC774\uC544\uBAAC\uB4DC\uC758 \uC9C8\uB7C9\uC758 \uB2E8\uC704\uC5D0\uB294 \uB300\uBD80\uBD84\uC758 \uBCF4\uC11D\uC758 \uC9C8\uB7C9\uC758 \uB2E8\uC704\uB85C \uC4F0\uC774\uB294 \uCE90\uB7FF\uC744 \uC4F4\uB2E4(1\uCE90\uB7FF=0.2g). 0.25\uCE90\uB7FF \uC774\uD558\uB85C \uC138\uACF5\uB41C, \uD06C\uAE30\uAC00 \uC791\uC740 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uBA5C\uB808(melee)\uB77C\uACE0 \uBD80\uB978\uB2E4. \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 4\uC6D4\uC758 \uD0C4\uC0DD\uC11D\uC774\uBA70, \uC138\uACC4\uC801\uC73C\uB85C \uC720\uBA85\uD55C 4\uB300 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uC0C1\uC2DC\uC640 \uB9AC\uC804\uD2B8, \uBE14\uB8E8 \uD638\uD504, \uD53C\uB80C\uCCB4 \uB2E4\uC774\uC544\uBAAC\uB4DC\uC774\uB2E4. \uC138\uACC4\uC5D0\uC11C \uAC00\uC7A5 \uC544\uB984\uB2E4\uC6B4 \uBCF4\uC11D\uC73C\uB85C \uAF3D\uD788\uAE30\uB3C4 \uD55C\uB2E4. \uC138\uACC4\uC5D0\uC11C \uAC00\uC7A5 \uD070 \uB294 \uC544\uD504\uB9AC\uCE74\uC758 \uD504\uB808\uBBF8\uC5C4 \uAD11\uC0B0\uC5D0\uC11C \uBC1C\uACAC\uB41C \uB85C \uD604\uC7AC 9\uAC1C\uC758 \uD070 \uC870\uAC01\uACFC 96\uAC1C\uC758 \uC791\uC740 \uC870\uAC01\uC73C\uB85C \uCABC\uAC1C\uC84C\uB2E4."@ko . . . "( \uB2E4\uB978 \uB73B\uC5D0 \uB300\uD574\uC11C\uB294 \uB2E4\uC774\uC544\uBAAC\uB4DC (\uB3D9\uC74C\uC774\uC758) \uBB38\uC11C\uB97C \uCC38\uACE0\uD558\uC2ED\uC2DC\uC624.) \uB2E4\uC774\uC544\uBAAC\uB4DC(\uC601\uC5B4: diamond) \uB610\uB294 \uAE08\uAC15\uC11D(\u91D1\u525B\u77F3)\uC740 \uCC9C\uC5F0\uAD11\uBB3C\uC911 \uAC00\uC7A5 \uAD73\uAE30\uAC00 \uC6B0\uC218\uD558\uBA70 \uAD11\uCC44\uAC00 \uB6F0\uC5B4\uB09C \uBCF4\uC11D\uC774\uB2E4. \uC8FC\uC131\uBD84\uC740 \uD0C4\uC18C\uC774\uBA70 \uBD84\uC790\uAD6C\uC870\uC0C1\uC758 \uCC28\uC774\uB85C \uC778\uD574 \uB3D9\uC77C\uD55C \uC6D0\uC790\uB85C \uAD6C\uC131\uB41C \uC790\uC5F0 \uC0B0\uBB3C\uC778 \uD751\uC5F0\uACFC\uB294 \uB9E4\uC6B0 \uB2E4\uB978 \uD2B9\uC131\uC744 \uAC00\uC9C4 \uBCF4\uC11D\uC774\uB2E4. \uB6F0\uC5B4\uB09C \uACBD\uB3C4\uB85C \uC778\uD574 \uACF5\uC5C5\uC6A9\uC73C\uB85C\uB3C4 \uB9CE\uC774 \uC4F0\uC774\uB098, \uB300\uBD80\uBD84\uC758 \uACF5\uC5C5\uC6A9 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uC778\uAC04\uC774 \uB9CC\uB4E0 \uC778\uC870 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB97C \uC4F4\uB2E4. \uD604\uC7AC\uC5D0 \uC774\uB974\uB7EC\uC11C\uB294 \uC9C8\uC774 \uB098\uC05C \uC790\uC5F0 \uB2E4\uC774\uC544\uBAAC\uB4DC\uC640 \uC9C8\uC774 \uC88B\uC740 \uACF5\uC5C5\uC6A9 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB97C \uC2DD\uBCC4\uD558\uAE30 \uC5B4\uB835\uB2E4. \uD754\uD788 \uB2E4\uC774\uC544\uBAAC\uB4DC\uC758 \uC9C8\uB7C9\uC758 \uB2E8\uC704\uC5D0\uB294 \uB300\uBD80\uBD84\uC758 \uBCF4\uC11D\uC758 \uC9C8\uB7C9\uC758 \uB2E8\uC704\uB85C \uC4F0\uC774\uB294 \uCE90\uB7FF\uC744 \uC4F4\uB2E4(1\uCE90\uB7FF=0.2g). 0.25\uCE90\uB7FF \uC774\uD558\uB85C \uC138\uACF5\uB41C, \uD06C\uAE30\uAC00 \uC791\uC740 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uBA5C\uB808(melee)\uB77C\uACE0 \uBD80\uB978\uB2E4. \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uAC15\uB3C4\uC5D0 \uB530\uB77C \uD654\uC528 1400\uB3C4\uBD80\uD130 1607\uB3C4 \uC0AC\uC774\uC5D0\uC11C \uC644\uC804\uD788 \uC5F0\uC18C\uB41C\uB2E4. \uC2E4\uC81C\uB85C \uB2E4\uC774\uC544\uBAAC\uB4DC\uAC00 \uD615\uC131\uB418\uB294 \uACF3\uC740 \uB545\uC18D \uAE4A\uC774 130\uD0AC\uB85C\uBBF8\uD130 \uC544\uB798\uC5D0\uC11C\uC774\uB2E4. \uB545 \uC704\uC5D0\uC11C \uBC1C\uACAC\uB418\uB294 \uAC83\uC740 \uD654\uC0B0\uC774 \uBD84\uCD9C\uD560 \uB54C \uD568\uAED8 \uB545 \uC704\uB85C \uC19F\uC544\uC624\uB978 \uAC83\uC774\uB2E4. \uBCF4\uD1B5 \uC0C9\uAE54\uC774 \uC5C6\uB294 \uAC83\uC744 \uADC0\uD558\uAC8C \uC0DD\uAC01\uD558\uBA70, \uAC04\uD639 \uB9E4\uC6B0 \uD2B9\uBCC4\uD55C \uC0C9\uAE54\uC758 \uAC83\uC774 \uAC00\uCE58\uB97C \uC778\uC815\uBC1B\uB294 \uACBD\uC6B0\uB3C4 \uC788\uB2E4. \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uB450 \uBC88\uC9F8\uB85C \uB2E8\uB2E8\uD55C \uAC15\uC625\uBCF4\uB2E4 90\uBC30\uB098 \uB354 \uB2E8\uB2E8\uD558\uB2E4. \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 4\uC6D4\uC758 \uD0C4\uC0DD\uC11D\uC774\uBA70, \uC138\uACC4\uC801\uC73C\uB85C \uC720\uBA85\uD55C 4\uB300 \uB2E4\uC774\uC544\uBAAC\uB4DC\uB294 \uC0C1\uC2DC\uC640 \uB9AC\uC804\uD2B8, \uBE14\uB8E8 \uD638\uD504, \uD53C\uB80C\uCCB4 \uB2E4\uC774\uC544\uBAAC\uB4DC\uC774\uB2E4. \uC138\uACC4\uC5D0\uC11C \uAC00\uC7A5 \uC544\uB984\uB2E4\uC6B4 \uBCF4\uC11D\uC73C\uB85C \uAF3D\uD788\uAE30\uB3C4 \uD55C\uB2E4. \uC138\uACC4\uC5D0\uC11C \uAC00\uC7A5 \uD070 \uB294 \uC544\uD504\uB9AC\uCE74\uC758 \uD504\uB808\uBBF8\uC5C4 \uAD11\uC0B0\uC5D0\uC11C \uBC1C\uACAC\uB41C \uB85C \uD604\uC7AC 9\uAC1C\uC758 \uD070 \uC870\uAC01\uACFC 96\uAC1C\uC758 \uC791\uC740 \uC870\uAC01\uC73C\uB85C \uCABC\uAC1C\uC84C\uB2E4."@ko . . . "\uB2E4\uC774\uC544\uBAAC\uB4DC"@ko . . . . . . . . . "Diamante"@es . . . . . "\u947D\u77F3\uFF08\u53E4\u5E0C\u814A\u8A9E\uFF1A\u1F00\u03B4\u03AC\u03BC\u03B1\u03C2\uFF1B\u6CD5\u8A9E\u3001\u5FB7\u8A9E\uFF1ADiamant\uFF1B\u82F1\u8A9E\uFF1ADiamond\uFF1B\u4FC4\u8A9E\uFF1A\u0410\u043B\u043C\u0430\u0437\uFF09\uFF0C\u70BA\u4E94\u7A2E\u6A1E\u8981\u5BF6\u77F3\u7684\u4E00\u7A2E\uFF0C\u5316\u5B66\u548C\u5DE5\u4E1A\u61C9\u7528\u4E2D\u79F0\u4E3A\u91D1\u525B\u77F3\u3002\u947D\u77F3\u662F\u78B3\u5143\u7D20\u7EC4\u6210\u7684\u7121\u8272\u6676\u4F53\uFF0C\u70BA\u76EE\u524D\u5DF2\u77E5\u786C\u5EA6\u50C5\u6B21\u65BC\u85CD\u7D72\u9EDB\u723E\u77F3\u7684\u5929\u7136\u7269\u8CEA\u3002"@zh . . "\u0410\u043B\u043C\u0430\u0437"@ru . . . . . . . . "H-M symbol:"@en . . . . . . . . "Diamantea (antzinako grezieraz, \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2\u2013ad\u00E1mas\u2013\"apurezina\") karbonoaren alotropo bat da, non karbonoaren atomoak kristal-egitura kubikoaren aldaera batean kokatuta dauden. Aldaera hori \u201Cdiamantearen sarea\u201D deritzon aldean zentratuta dago.Grafitoaren ondoren, karbonoaren bigarren eiterik egonkorrena da; hala ere, ingurune-baldintzetan, diamantetik grafitora bihurtzeko tasa baztergarria da. Ezagutzen den material naturalik gogorrena da, eta material gogorrenetan hirugarrena, diamantezko nanohagaxka agregatuen eta ultragogorraren ondoren. Famatua da bere atomoen arteko lotura kobalenteak itzelezko ezaugarriak ematen dizkiolako, are gehiago, diamantea da gizakiak ezagutzen duen gogortasunik, dispertsiorik eta eroankortasun termikorik handiena daukan minerala. Ezaugarri horiek baliatuz mozteko eta leuntzeko tresnak egiteko erabiltzen da diamantea, eta bitxigintzarako ere bai. Gogortasunak eta argiaren dispertsio handiak material egokia bihurtzen dute hainbat aplikazio industrialetarako eta bitxigintzarako. Diamantea mineral arraroa da, karbono puruz osatua kristalizatua, tetraedroetan, ibaietako metaketetan edota harri-hobietan topatzen da. Bere pisu espezifikoa 3,5ekoa da eta munduan dauden material naturalen artean gogorrena da. Harribitxi-kalitatea dutenak oso preziatuak dira distirarengatik eta beren alde poligonalek argia errefraktatzeko duten ahalmenagatik. Diamanteen pisua kilatetan neurtzen da (kilate bat 0,2 g dira)."@eu . . "Isotropic"@en . . . . . . . . . . . . . . "Diament \u2013 bardzo rzadki minera\u0142 z gromady pierwiastk\u00F3w rodzimych. Nazwa pochodzi od stgr. \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 adamas (dope\u0142niacz \u1F00\u03B4\u03AC\u03BC\u03B1\u03BD\u03C4\u03BF\u03C2 adamantos, \u0142ac. diamentum) \u201Bniepokonany, niezniszczalny\u2019 i nawi\u0105zuje do jego wyj\u0105tkowej twardo\u015Bci. Jest najtwardsz\u0105 znan\u0105 substancj\u0105 wyst\u0119puj\u0105c\u0105 w przyrodzie. Antoine Lavoisier po raz pierwszy spali\u0142 diament pod szklanym kloszem, u\u017Cywaj\u0105c promieni s\u0142onecznych skupionych soczewk\u0105. Udowodni\u0142 w ten spos\u00F3b, \u017Ce diament to czysty w\u0119giel."@pl . . . . . "Diamantea (antzinako grezieraz, \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2\u2013ad\u00E1mas\u2013\"apurezina\") karbonoaren alotropo bat da, non karbonoaren atomoak kristal-egitura kubikoaren aldaera batean kokatuta dauden. Aldaera hori \u201Cdiamantearen sarea\u201D deritzon aldean zentratuta dago.Grafitoaren ondoren, karbonoaren bigarren eiterik egonkorrena da; hala ere, ingurune-baldintzetan, diamantetik grafitora bihurtzeko tasa baztergarria da. Ezagutzen den material naturalik gogorrena da, eta material gogorrenetan hirugarrena, diamantezko nanohagaxka agregatuen eta ultragogorraren ondoren. Famatua da bere atomoen arteko lotura kobalenteak itzelezko ezaugarriak ematen dizkiolako, are gehiago, diamantea da gizakiak ezagutzen duen gogortasunik, dispertsiorik eta eroankortasun termikorik handiena daukan minerala. Ezaugarri horiek baliatuz mozteko "@eu . . . . . . . . . . "Diamant je t\u00E9m\u011B\u0159 nejtvrd\u0161\u00ED zn\u00E1m\u00FD p\u0159\u00EDrodn\u00ED miner\u00E1l (nerost) a jedna z nejtvrd\u0161\u00EDch l\u00E1tek v\u016Fbec (tvrd\u0161\u00ED jsou nap\u0159. fullerit, romboedrick\u00E1 modifikace diamantu \u010Di nanokrystalick\u00E1 forma diamantu \u2013 ADNR). Jedn\u00E1 se o krystalickou formu uhl\u00EDku C. Tvo\u0159\u00ED hlavn\u011B jednotliv\u00E9 krystaly oktaedrick\u00E9ho, dodekaedrick\u00E9ho nebo krychlov\u00E9ho vzhledu, typick\u00FD je vypoukl\u00FD a vz\u00E1cn\u011B a\u017E kulovit\u00FD tvar krystal\u016F. Diamanty \u010Dasto tvo\u0159\u00ED srostlice krystal\u016F. Pro pou\u017Eit\u00ED ve \u0161perku je nejobl\u00EDben\u011Bj\u0161\u00ED v\u00FDbrus naz\u00FDvan\u00FD briliant."@cs . . . . "Diamant (Oudgrieks: \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 of adamas, \"onverslaanbaar\") is een allotrope verschijningsvorm van koolstof die als delfstof aangetroffen wordt, maar ook in laboratoria gemaakt kan worden. In diamant hebben de koolstof-koolstofbindingen een viervlakstructuur waardoor de atomen in drie dimensies gebonden zijn; dit verklaart deels de hardheid waar het mineraal zijn naam aan dankt. Daarentegen heeft grafiet, de koolstofvorm die op aarde het meest voorkomt, een vlakke kristalstructuur waardoor het veel zachter is en schilferende laagjes vormt. Diamant is voor zover bekend het hardste materiaal dat in de natuur voorkomt en is dan ook het ijkpunt voor hardheid 10 op de hardheidsschaal van Mohs. Slechts enkele industrieel vervaardigde, eveneens uit zuivere koolstof opgebouwde materialen zijn harder."@nl . "Diamond is a solid form of the element carbon with its atoms arranged in a crystal structure called diamond cubic. Another solid form of carbon known as graphite is the chemically stable form of carbon at room temperature and pressure, but diamond is metastable and converts to it at a negligible rate under those conditions. Diamond has the highest hardness and thermal conductivity of any natural material, properties that are used in major industrial applications such as cutting and polishing tools. They are also the reason that diamond anvil cells can subject materials to pressures found deep in the Earth. Because the arrangement of atoms in diamond is extremely rigid, few types of impurity can contaminate it (two exceptions are boron and nitrogen). Small numbers of defects or impurities (about one per million of lattice atoms) color diamond blue (boron), yellow (nitrogen), brown (defects), green (radiation exposure), purple, pink, orange, or red. Diamond also has a very high refractive index and a relatively high optical dispersion. Most natural diamonds have ages between 1 billion and 3.5 billion years. Most were formed at depths between 150 and 250 kilometres (93 and 155 mi) in the Earth's mantle, although a few have come from as deep as 800 kilometres (500 mi). Under high pressure and temperature, carbon-containing fluids dissolved various minerals and replaced them with diamonds. Much more recently (hundreds to tens of million years ago), they were carried to the surface in volcanic eruptions and deposited in igneous rocks known as kimberlites and lamproites. Synthetic diamonds can be grown from high-purity carbon under high pressures and temperatures or from hydrocarbon gases by chemical vapor deposition (CVD). Imitation diamonds can also be made out of materials such as cubic zirconia and silicon carbide. Natural, synthetic and imitation diamonds are most commonly distinguished using optical techniques or thermal conductivity measurements."@en . . . . . . . . . . . . . . . "Intan atau berlian (bahasa Belanda: briljant) adalah benda berharga mineral yang secara kimia merupakan bentuk kristal, atau alotrop, dari karbon. Intan terkenal karena memiliki sifat-sifat fisika yang istimewa, terutama faktor kekerasannya yang bisa mencapai skala kekerasan Mohs tingkat tertinggi (10) dan kemampuannya mendispersikan cahaya. Sifat-sifat ini yang membuat intan digunakan dalam perhiasan dan berbagai penerapan di dalam dunia industri."@in . . . . . . . . . . . . . "El diamant (del grec ad\u00E1mas, que significa \"apropiat\" o \"inalterable\") \u00E9s un mineral, al\u00B7l\u00F2trop del carboni en qu\u00E8 els \u00E0toms estan configurats en una variaci\u00F3 de l'estructura cristal\u00B7lina c\u00FAbica centrada en les cares anomenada . El diamant \u00E9s la segona forma m\u00E9s estable de carboni despr\u00E9s del grafit; tanmateix, la velocitat de conversi\u00F3 de diamant en grafit \u00E9s negligible en condicions ambientals. El diamant \u00E9s especialment conegut per ser un material amb qualitats f\u00EDsiques excepcionals, moltes de les quals s\u00F3n degudes als forts enlla\u00E7os covalents que hi ha entre els seus \u00E0toms. En particular, el diamant t\u00E9 la duresa i la conductivitat t\u00E8rmica m\u00E9s altes de tots els materials. Aquestes propietats determinen l'\u00FAs industrial principal del diamant en eines de tall i de poliment."@ca . "C1C3CC5CC1CCC36C3CCCC6CC1C3"@en . . . . . "diamond"@en . . . 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"no"@en . . . . . . "Diamant"@cs . . . "1.3"^^ . . . "\u94BB\u77F3"@zh . . . . . . . . . . . . "Intan atau berlian (bahasa Belanda: briljant) adalah benda berharga mineral yang secara kimia merupakan bentuk kristal, atau alotrop, dari karbon. Intan terkenal karena memiliki sifat-sifat fisika yang istimewa, terutama faktor kekerasannya yang bisa mencapai skala kekerasan Mohs tingkat tertinggi (10) dan kemampuannya mendispersikan cahaya. Sifat-sifat ini yang membuat intan digunakan dalam perhiasan dan berbagai penerapan di dalam dunia industri. Intan terutama ditambang di Afrika tengah dan selatan, walaupun kandungan intan yang signifikan juga telah ditemukan di Kanada, Rusia, Brasil, dan Australia. Sekitar 130 juta \"carat\" (26.000 kg) intan ditambang setiap tahun, yang berjumlah kira-kira 9 miliar dollar Amerika Serikat. Selain itu, hampir empat kali berat intan dibuat di dalam makmal sebagai intan sintetik (synthetic diamond) yang memiliki skala kekerasan Mohs 11, yang hanya bisa dibuat di laboratorium."@in . "Diamanto estas unu el la naturaj alotropoj de karbono, tio estas solida formo de la elemento karbon kun siaj atomoj aran\u011Ditaj en kristala strukturo nome diamanta kubo. La \u0109efa alotropo estas grafito. \u011Ci estas gemo, uzata por juveloj. Je normaj kondi\u0109oj pri temperaturo kaj premo, alia solida formo de karbono konata kiel grafito estas la kemie stabila formo, sed diamantoj preska\u016D neniam konverti\u011Das al tio. Diamantoj havas la plej altajn malmolecon kaj termikan konduktivon de ajna natura materialo, propra\u0135oj kiuj estas uzataj en gravaj industriaj aplika\u0135oj kiel tran\u0109ado kaj polurado de iloj. Ili estas anka\u016D tialo ke diamantaj ambosaj \u0109eloj povas meti materialojn al premoj trovitaj profunde en la Tero."@eo . . "El diamant (del grec ad\u00E1mas, que significa \"apropiat\" o \"inalterable\") \u00E9s un mineral, al\u00B7l\u00F2trop del carboni en qu\u00E8 els \u00E0toms estan configurats en una variaci\u00F3 de l'estructura cristal\u00B7lina c\u00FAbica centrada en les cares anomenada . El diamant \u00E9s la segona forma m\u00E9s estable de carboni despr\u00E9s del grafit; tanmateix, la velocitat de conversi\u00F3 de diamant en grafit \u00E9s negligible en condicions ambientals. El diamant \u00E9s especialment conegut per ser un material amb qualitats f\u00EDsiques excepcionals, moltes de les quals s\u00F3n degudes als forts enlla\u00E7os covalents que hi ha entre els seus \u00E0toms. En particular, el diamant t\u00E9 la duresa i la conductivitat t\u00E8rmica m\u00E9s altes de tots els materials. Aquestes propietats determinen l'\u00FAs industrial principal del diamant en eines de tall i de poliment. Els diamants tenen unes caracter\u00EDstiques \u00F2ptiques notables. A causa del seu reticle extremament r\u00EDgid, nom\u00E9s els poden contaminar molt poques impureses, com ara el bor i el nitrogen. En combinaci\u00F3 amb la seva gran transpar\u00E8ncia, aix\u00F2 dona com a resultat l'espectaclar i incolor de la majoria de diamants naturals. Petites quantitats de defectes o impureses (aproximadament una per mili\u00F3 d'\u00E0toms del reticle) acoloreixen el diamant de blau (bor), groc (nitrogen), marr\u00F3 (defectes cristal\u00B7lins, verd, lila, rosa, taronja o vermell). El diamant tamb\u00E9 t\u00E9 una dispersi\u00F3 \u00F2ptica relativament alta, \u00E9s a dir, una gran capacitat de dispersar la llum de diferents colors, cosa que dona com a resultat la seva llu\u00EFssor caracter\u00EDstica. Les seves propietats \u00F2ptiques i mec\u00E0niques, juntament amb un m\u00E0rqueting efica\u00E7, fan que el diamant sigui una gemma popular. La majoria de diamants naturals es formen a les condicions de pressi\u00F3 i temperatura elevades que es donen a profunditats d'entre 140 i 190 quil\u00F2metres al mantell. Els minerals amb carboni proporcionen la font de carboni, i el creixement es perllonga durant per\u00EDodes d'entre 1.000 i 3.000 milions d'anys, cosa que correspon a aproximadament un 25% i un 75% de l'edat de la Terra, respectivament. Els diamants s\u00F3n portats a prop de la superf\u00EDcie de la Terra gr\u00E0cies a erupcions volc\u00E0niques profundes, per magma que es refreda en roques \u00EDgnies conegudes com a kimberlites i lampro\u00EFtes. Els diamants tamb\u00E9 es poden produir sint\u00E8ticament en un proc\u00E9s d'alta pressi\u00F3 i temperatura que simula de manera aproximada les condicions al mantell terrestre. Una t\u00E8cnica de producci\u00F3 alternativa i completament diferent \u00E9s la deposici\u00F3 qu\u00EDmica de vapor. Diversos materials no diamants, que inclouen la zirc\u00F2nia c\u00FAbica i el carbur de silici i sovint reben el nom de , s'assemblen als diamants en l'aspecte i en moltes propietats. S'han desenvolupat t\u00E8cniques gemmol\u00F2giques especials per distingir els diamants naturals i sint\u00E8tics i els simulants."@ca . . "Il diamante \u00E8 una delle tante forme allotropiche in cui pu\u00F2 presentarsi il carbonio; in particolare il diamante \u00E8 costituito da un reticolo cristallino di atomi di carbonio disposti secondo una struttura particolare detta tetraedrica. Il diamante \u00E8 il pi\u00F9 duro dei minerali conosciuti e rappresenta uno dei pochi casi in cui un elemento (il carbonio) si rinviene in discreti quantitativi in natura allo stato puro."@it . . . . . . . . . . . . . . . "Diamant (Oudgrieks: \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 of adamas, \"onverslaanbaar\") is een allotrope verschijningsvorm van koolstof die als delfstof aangetroffen wordt, maar ook in laboratoria gemaakt kan worden. In diamant hebben de koolstof-koolstofbindingen een viervlakstructuur waardoor de atomen in drie dimensies gebonden zijn; dit verklaart deels de hardheid waar het mineraal zijn naam aan dankt. Daarentegen heeft grafiet, de koolstofvorm die op aarde het meest voorkomt, een vlakke kristalstructuur waardoor het veel zachter is en schilferende laagjes vormt. Diamant is voor zover bekend het hardste materiaal dat in de natuur voorkomt en is dan ook het ijkpunt voor hardheid 10 op de hardheidsschaal van Mohs. Slechts enkele industrieel vervaardigde, eveneens uit zuivere koolstof opgebouwde materialen zijn harder."@nl . . "Fdm"@en . . . . . . . . . . . . . . . . . "Diament"@pl . . . . "no"@en . . . . . . . . . . . "\u0410\u043B\u043C\u0430\u0301\u0437 (\u0432\u0456\u0434 \u0430\u0440\u0430\u0431. \u0623\u0644\u0645\u0627\u0633\u200E, alm\u0101s \u2014 \u043D\u0435\u0437\u0434\u043E\u043B\u0430\u043D\u043D\u0438\u0439, \u0430\u043D\u0433\u043B. diamond; \u043D\u0456\u043C. Diamant) \u2014 \u043C\u0456\u043D\u0435\u0440\u0430\u043B \u043A\u043B\u0430\u0441\u0443 \u0441\u0430\u043C\u043E\u0440\u043E\u0434\u043D\u0438\u0445 \u043D\u0435\u043C\u0435\u0442\u0430\u043B\u0456\u0432, \u0442\u0432\u0435\u0440\u0434\u0430 \u043A\u0440\u0438\u0441\u0442\u0430\u043B\u0456\u0447\u043D\u0430 \u0430\u043B\u043E\u0442\u0440\u043E\u043F\u043D\u0430 \u0432\u0438\u0434\u043E\u0437\u043C\u0456\u043D\u0430 \u043A\u0430\u0440\u0431\u043E\u043D\u0443 \u043A\u0443\u0431\u0456\u0447\u043D\u043E\u0457 \u0441\u0438\u043D\u0433\u043E\u043D\u0456\u0457."@uk . "Diamond"@en . . . . . "Intan"@in . . . . . "1"^^ . . . . . . . . . . . . . . . . . . "3.5"^^ . . . . . "Colorless"@en . . . . . . . . . "Diamond"@en . . . . . . . . . . . . . . . "8082"^^ . . . . . . . . . . . . . . . "Hexoctahedral"@en . . . . . . . "\u0410\u043B\u043C\u0430\u0301\u0437 (\u043E\u0442 \u043F\u0440\u0430\u0442\u044E\u0440\u043A. almaz, \u0431\u0443\u043A\u0432. \u00AB\u043D\u0435\u043F\u043E\u0434\u0434\u0430\u044E\u0449\u0438\u0439\u0441\u044F\u00BB, \u0447\u0435\u0440\u0435\u0437 \u0430\u0440\u0430\u0431. \u0623\u0644\u0645\u0627\u0633\u200E [\u2019alm\u0101s] \u0438 \u0432 \u0434\u0440.-\u0433\u0440\u0435\u0447. \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 \u00AB\u043D\u0435\u0441\u043E\u043A\u0440\u0443\u0448\u0438\u043C\u044B\u0439\u00BB) \u2014 \u043C\u0438\u043D\u0435\u0440\u0430\u043B, \u043A\u0443\u0431\u0438\u0447\u0435\u0441\u043A\u0430\u044F \u0430\u043B\u043B\u043E\u0442\u0440\u043E\u043F\u043D\u0430\u044F \u0444\u043E\u0440\u043C\u0430 \u0443\u0433\u043B\u0435\u0440\u043E\u0434\u0430. \u041F\u0440\u0438 \u043D\u043E\u0440\u043C\u0430\u043B\u044C\u043D\u044B\u0445 \u0443\u0441\u043B\u043E\u0432\u0438\u044F\u0445 \u043C\u0435\u0442\u0430\u0441\u0442\u0430\u0431\u0438\u043B\u0435\u043D, \u0442\u043E \u0435\u0441\u0442\u044C \u043C\u043E\u0436\u0435\u0442 \u0441\u0443\u0449\u0435\u0441\u0442\u0432\u043E\u0432\u0430\u0442\u044C \u043D\u0435\u043E\u0433\u0440\u0430\u043D\u0438\u0447\u0435\u043D\u043D\u043E \u0434\u043E\u043B\u0433\u043E. \u0412 \u0432\u0430\u043A\u0443\u0443\u043C\u0435 \u0438\u043B\u0438 \u0432 \u0438\u043D\u0435\u0440\u0442\u043D\u043E\u043C \u0433\u0430\u0437\u0435 \u043F\u0440\u0438 \u043F\u043E\u0432\u044B\u0448\u0435\u043D\u043D\u044B\u0445 \u0442\u0435\u043C\u043F\u0435\u0440\u0430\u0442\u0443\u0440\u0430\u0445 \u043F\u043E\u0441\u0442\u0435\u043F\u0435\u043D\u043D\u043E \u043F\u0435\u0440\u0435\u0445\u043E\u0434\u0438\u0442 \u0432 \u0433\u0440\u0430\u0444\u0438\u0442. \u0421\u0430\u043C\u044B\u0439 \u0442\u0432\u0451\u0440\u0434\u044B\u0439 \u043F\u043E \u0448\u043A\u0430\u043B\u0435 \u044D\u0442\u0430\u043B\u043E\u043D\u043D\u044B\u0445 \u043C\u0438\u043D\u0435\u0440\u0430\u043B\u043E\u0432 \u0442\u0432\u0451\u0440\u0434\u043E\u0441\u0442\u0438 \u041C\u043E\u043E\u0441\u0430."@ru . . "Diamond is a solid form of the element carbon with its atoms arranged in a crystal structure called diamond cubic. Another solid form of carbon known as graphite is the chemically stable form of carbon at room temperature and pressure, but diamond is metastable and converts to it at a negligible rate under those conditions. Diamond has the highest hardness and thermal conductivity of any natural material, properties that are used in major industrial applications such as cutting and polishing tools. They are also the reason that diamond anvil cells can subject materials to pressures found deep in the Earth."@en . . "Diamante"@eu . . . . . . . . "\u0410\u043B\u043C\u0430\u0301\u0437 (\u043E\u0442 \u043F\u0440\u0430\u0442\u044E\u0440\u043A. almaz, \u0431\u0443\u043A\u0432. \u00AB\u043D\u0435\u043F\u043E\u0434\u0434\u0430\u044E\u0449\u0438\u0439\u0441\u044F\u00BB, \u0447\u0435\u0440\u0435\u0437 \u0430\u0440\u0430\u0431. \u0623\u0644\u0645\u0627\u0633\u200E [\u2019alm\u0101s] \u0438 \u0432 \u0434\u0440.-\u0433\u0440\u0435\u0447. \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 \u00AB\u043D\u0435\u0441\u043E\u043A\u0440\u0443\u0448\u0438\u043C\u044B\u0439\u00BB) \u2014 \u043C\u0438\u043D\u0435\u0440\u0430\u043B, \u043A\u0443\u0431\u0438\u0447\u0435\u0441\u043A\u0430\u044F \u0430\u043B\u043B\u043E\u0442\u0440\u043E\u043F\u043D\u0430\u044F \u0444\u043E\u0440\u043C\u0430 \u0443\u0433\u043B\u0435\u0440\u043E\u0434\u0430. \u041F\u0440\u0438 \u043D\u043E\u0440\u043C\u0430\u043B\u044C\u043D\u044B\u0445 \u0443\u0441\u043B\u043E\u0432\u0438\u044F\u0445 \u043C\u0435\u0442\u0430\u0441\u0442\u0430\u0431\u0438\u043B\u0435\u043D, \u0442\u043E \u0435\u0441\u0442\u044C \u043C\u043E\u0436\u0435\u0442 \u0441\u0443\u0449\u0435\u0441\u0442\u0432\u043E\u0432\u0430\u0442\u044C \u043D\u0435\u043E\u0433\u0440\u0430\u043D\u0438\u0447\u0435\u043D\u043D\u043E \u0434\u043E\u043B\u0433\u043E. \u0412 \u0432\u0430\u043A\u0443\u0443\u043C\u0435 \u0438\u043B\u0438 \u0432 \u0438\u043D\u0435\u0440\u0442\u043D\u043E\u043C \u0433\u0430\u0437\u0435 \u043F\u0440\u0438 \u043F\u043E\u0432\u044B\u0448\u0435\u043D\u043D\u044B\u0445 \u0442\u0435\u043C\u043F\u0435\u0440\u0430\u0442\u0443\u0440\u0430\u0445 \u043F\u043E\u0441\u0442\u0435\u043F\u0435\u043D\u043D\u043E \u043F\u0435\u0440\u0435\u0445\u043E\u0434\u0438\u0442 \u0432 \u0433\u0440\u0430\u0444\u0438\u0442. \u0421\u0430\u043C\u044B\u0439 \u0442\u0432\u0451\u0440\u0434\u044B\u0439 \u043F\u043E \u0448\u043A\u0430\u043B\u0435 \u044D\u0442\u0430\u043B\u043E\u043D\u043D\u044B\u0445 \u043C\u0438\u043D\u0435\u0440\u0430\u043B\u043E\u0432 \u0442\u0432\u0451\u0440\u0434\u043E\u0441\u0442\u0438 \u041C\u043E\u043E\u0441\u0430."@ru . . . . . . . . . . . . . . . . . . . . . . "Diamant (grekiska \u03B1\u03B4\u03AC\u03BC\u03B1\u03C2 adamas, o\u00F6vervinnerlig) \u00E4r en allotrop av grund\u00E4mnet kol. Till skillnad fr\u00E5n grafit och fulleren (som ocks\u00E5 best\u00E5r av kol) \u00E4r den mycket h\u00E5rd. Diamant \u00E4r en \u00E4delsten och tack vare sin h\u00E5rdhet anv\u00E4nd i industrin som sk\u00E4r- och slipmedel. Oslipade diamanter kallas r\u00E5diamanter. Inom industrin anv\u00E4nds inte vanliga diamanter utan syntetiska s\u00E5dana."@sv . . . . . . . . . . . . . . . . "Diamant (grekiska \u03B1\u03B4\u03AC\u03BC\u03B1\u03C2 adamas, o\u00F6vervinnerlig) \u00E4r en allotrop av grund\u00E4mnet kol. Till skillnad fr\u00E5n grafit och fulleren (som ocks\u00E5 best\u00E5r av kol) \u00E4r den mycket h\u00E5rd. Diamant \u00E4r en \u00E4delsten och tack vare sin h\u00E5rdhet anv\u00E4nd i industrin som sk\u00E4r- och slipmedel. Oslipade diamanter kallas r\u00E5diamanter. Inom industrin anv\u00E4nds inte vanliga diamanter utan syntetiska s\u00E5dana."@sv . . . . . . . . . . . . . "Dia"@en . . . . "O diamante \u00E9 um cristal sob uma forma alotr\u00F3pica do carbono, de f\u00F3rmula qu\u00EDmica C. \u00C9 a forma triangular est\u00E1vel do carbono em press\u00F5es acima de 6 GPa (60 kbar). Comercializados como pedras preciosas, os diamantes possuem um alto valor agregado. Normalmente, o diamante cristaliza com estrutura c\u00FAbica e pode ser sintetizado industrialmente. Outra forma de cristaliza\u00E7\u00E3o do diamante \u00E9 a hexagonal, menos comum na natureza e com dureza menor (9,5 na escala de Mohs). A caracter\u00EDstica que difere os diamantes de outras formas alotr\u00F3picas, \u00E9 o fato de cada \u00E1tomo de carbono estar hibridizado em sp\u00B3, e encontrar-se ligado a outros 4 \u00E1tomos de carbono por meio de liga\u00E7\u00F5es covalentes em um arranjo tridimensional tetra\u00E9drico. O diamante pode ser convertido em grafite, o al\u00F3tropo termodinamicamente est\u00E1vel em baixas press\u00F5es, aplicando-se temperaturas acima de 1 500 \u00B0C sob v\u00E1cuo ou atmosfera inerte. Em condi\u00E7\u00F5es ambientes, essa convers\u00E3o \u00E9 extremamente lenta, tornando-se negligenciada. Cristaliza no sistema c\u00FAbico, geralmente em cristais com forma octa\u00E9drica (8 faces) ou hexaquisocta\u00E9drica (48 faces), frequentemente com superf\u00EDcies curvas, arredondadas, incolores ou coradas. Os diamantes de cor escura s\u00E3o pouco conhecidos e o seu valor como gema \u00E9 menor devido ao seu aspecto pouco atrativo. Diferente do que se pensou durante anos, os diamantes n\u00E3o s\u00E3o eternos, pois o carbono definha com o tempo, mas os diamantes duram mais que qualquer ser humano. Sendo carbono puro, o diamante arde quando exposto a uma chama, transformando-se em di\u00F3xido de carbono. \u00C9 sol\u00FAvel em diversos \u00E1cidos e infus\u00EDvel, exceto a altas press\u00F5es. O diamante \u00E9 o mais duro material de ocorr\u00EAncia natural que se conhece. Sua dureza \u00E9 superada pelos tamb\u00E9m compostos (sint\u00E9ticos) de carbono, grafeno e carbono acetil\u00EAnico linear (conhecido tamb\u00E9m como carbino). Isto significa que n\u00E3o pode ser riscado por nenhum outro mineral ou subst\u00E2ncia, exceto o pr\u00F3prio diamante, funcionando como um importante material abrasivo. No entanto, \u00E9 muito fr\u00E1gil, e isso deve-se \u00E0 clivagem octa\u00E9drica perfeita segundo (2o). Estas duas caracter\u00EDsticas fizeram com que o diamante n\u00E3o fosse talhado durante muitos anos. A maior jazida do mundo, revelada pela R\u00FAssia ao mundo em 2012, por\u00E9m de conhecimento do Kremlin desde 1970, tem capacidade para suprir diamantes, mesmo para uso industrial, pelos pr\u00F3ximos 3000 anos. A jazida conta com trilh\u00F5es de quilates, e conta com 10 vezes mais diamantes do que todas as jazidas conhecidas existentes no mundo hoje, juntas. Ela situa-se numa cratera com extens\u00E3o de 100 km entre a regi\u00E3o de Krasnoiarsk e da Rep\u00FAblica de Sakha na Sib\u00E9ria, R\u00FAssia. Tal cratera teve origem h\u00E1 35 milh\u00F5es de anos, com a queda de um asteroide, e seus diamantes s\u00E3o duas vezes mais resistentes, duros, do que os encontrados em outros lugares. A sua origem \u00E9 decorrente da press\u00E3o e do calor gerado no impacto. Tal durabilidade \u00E9 do interesse de certos setores industriais, pois \u00E9 \u00F3timo e de extrema utilidade para confec\u00E7\u00E3o de equipamentos das ind\u00FAstrias eletr\u00F4nica e \u00F3tica, assim como em equipamentos para perfura\u00E7\u00E3o do solo. Outras jazidas no mundo s\u00E3o da \u00C1frica do Sul. Outras jazidas importantes situam-se na R\u00FAssia (segundo maior produtor) e na Austr\u00E1lia (terceiro maior produtor), entre outras de menor import\u00E2ncia. Em outubro de 2019, um dos diamantes mais raros do mundo foi descoberto na Rep\u00FAblica de Sakha da Sib\u00E9ria; ele foi designado de \u201Cdiamante Matryoshka\u201D, em homenagem \u00E0s ic\u00F4nicas bonecas russas. O diamante mede apenas 4,8 mm x 4,9 mm x 2,8 mm, e dentro dele existe uma cavidade interna que cont\u00E9m outro diamante medindo apenas 1,6 mil\u00EDmetro c\u00FAbico. Ainda n\u00E3o foi estimado o valor da pedra, mas a empresa que a descobriu (ALROSA) disse que suas caracter\u00EDsticas a tornar\u00E1 uma das mais valiosas do mundo. A densidade \u00E9 de 3,48. O brilho \u00E9 adamantino, derivado do elevad\u00EDssimo \u00EDndice de refra\u00E7\u00E3o (2,42). Recorde-se que todos os minerais com \u00EDndice de refrac\u00E7\u00E3o maior ou igual a 1,9 possuem este brilho. No entanto, os cristais n\u00E3o cortados podem apresentar um brilho gorduroso. Pode apresentar fluoresc\u00EAncia, ou seja, a incid\u00EAncia dos raios ultravioleta produzem luminesc\u00EAncia com cores variadas originando colora\u00E7\u00F5es azul, rosa, amarela ou verde."@pt . . "Le diamant (/dja.m\u0251\u0303/) est l'allotrope de haute pression du carbone, m\u00E9tastable \u00E0 basses temp\u00E9rature et pression. Moins stable que le graphite et la lonsdal\u00E9ite qui sont les deux autres formes de cristallisation du carbone, sa renomm\u00E9e en tant que min\u00E9ral lui vient de ses propri\u00E9t\u00E9s physiques et des fortes liaisons covalentes entre ses atomes arrang\u00E9s selon un syst\u00E8me cristallin cubique. En particulier, le diamant est le mat\u00E9riau naturel le plus dur (avec l'indice maximal (10) sur l'\u00E9chelle de Mohs) et il poss\u00E8de une tr\u00E8s forte conductivit\u00E9 thermique. Ses propri\u00E9t\u00E9s font que le diamant trouve de nombreuses applications dans l'industrie comme outils de coupe et d'usinage, dans les sciences comme bistouris ou enclumes \u00E0 diamant et dans la joaillerie pour ses propri\u00E9t\u00E9s optiques. La majorit\u00E9 des diamants naturels se sont form\u00E9s dans des conditions de tr\u00E8s hautes temp\u00E9ratures et pressions \u00E0 des profondeurs de 140 \u00E0 190 kilom\u00E8tres dans le manteau terrestre. Leur croissance n\u00E9cessite de 1 \u00E0 3,3 milliards d'ann\u00E9es (entre 25 et 75 % de l'\u00E2ge de la Terre). Les diamants sont remont\u00E9s \u00E0 la surface par le magma d'\u00E9ruptions volcaniques profondes qui refroidit pour former une roche volcanique contenant les diamants, les kimberlites et les lampro\u00EFtes. Le mot provient du grec ancien \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 \u2013 ad\u00E1mas \u00AB indomptable \u00BB."@fr . . . . . . "Diamant"@ca . . . . . . . . . . . . . . . . . . . . . . . "0.044"^^ . . . . "\u03A4\u03BF \u03B4\u03B9\u03B1\u03BC\u03AC\u03BD\u03C4\u03B9 \u03AE \u03B1\u03B4\u03AC\u03BC\u03B1\u03BD\u03C4\u03B1\u03C2 (\u03B1\u03C1\u03C7. \u03B5\u03BB\u03BB\u03B7\u03BD. \u03B1\u03B4\u03AC\u03BC\u03B1\u03C2 = \u03B1\u03AE\u03C4\u03C4\u03B7\u03C4\u03BF\u03C2, \u03B1\u03BA\u03B1\u03C4\u03B1\u03BD\u03AF\u03BA\u03B7\u03C4\u03BF\u03C2, \u03BB\u03CC\u03B3\u03C9 \u03C4\u03B7\u03C2 \u03BC\u03B5\u03B3\u03AC\u03BB\u03B7\u03C2 \u03C3\u03BA\u03BB\u03B7\u03C1\u03CC\u03C4\u03B7\u03C4\u03AC\u03C2 \u03C4\u03BF\u03C5) \u03B5\u03AF\u03BD\u03B1\u03B9 \u03C0\u03B5\u03C1\u03AF\u03C6\u03B7\u03BC\u03BF \u03BF\u03C1\u03C5\u03BA\u03C4\u03CC \u03B3\u03B9\u03B1 \u03C4\u03B7\u03BD \u03B9\u03C3\u03C7\u03C5\u03C1\u03AE \u03BB\u03AC\u03BC\u03C8\u03B7 \u03C4\u03BF\u03C5 \u03BA\u03B1\u03B9 \u03C4\u03B7\u03BD \u03C0\u03BF\u03BB\u03CD \u03BC\u03B5\u03B3\u03AC\u03BB\u03B7 \u03C3\u03BA\u03BB\u03B7\u03C1\u03CC\u03C4\u03B7\u03C4\u03AC \u03C4\u03BF\u03C5, \u03BC\u03B5 \u03B9\u03B4\u03B9\u03B1\u03AF\u03C4\u03B5\u03C1\u03B7 \u03B4\u03B9\u03B5\u03B8\u03BD\u03AE \u03B5\u03BC\u03C0\u03BF\u03C1\u03B9\u03BA\u03AE \u03B1\u03BE\u03AF\u03B1. \u0391\u03BD\u03AE\u03BA\u03B5\u03B9 \u03C3\u03C4\u03B7\u03BD \u03BF\u03B9\u03BA\u03BF\u03B3\u03AD\u03BD\u03B5\u03B9\u03B1 \u03C4\u03C9\u03BD \u03B1\u03C5\u03C4\u03BF\u03C6\u03C5\u03CE\u03BD \u03C3\u03C4\u03BF\u03B9\u03C7\u03B5\u03AF\u03C9\u03BD. \u0391\u03C0\u03BF\u03C4\u03B5\u03BB\u03B5\u03AF\u03C4\u03B1\u03B9 \u03B1\u03C0\u03CC \u03BA\u03B1\u03B8\u03B1\u03C1\u03CC \u03AC\u03BD\u03B8\u03C1\u03B1\u03BA\u03B1. \u039B\u03CC\u03B3\u03C9 \u03C4\u03B7\u03C2 \u03C3\u03BA\u03BB\u03B7\u03C1\u03CC\u03C4\u03B7\u03C4\u03B1\u03C2 \u03B1\u03C5\u03C4\u03AE\u03C2 \u03C7\u03C1\u03B7\u03C3\u03B9\u03BC\u03BF\u03C0\u03BF\u03B9\u03B5\u03AF\u03C4\u03B1\u03B9 \u03C3\u03B5 \u03B2\u03B9\u03BF\u03BC\u03B7\u03C7\u03B1\u03BD\u03B9\u03BA\u03AD\u03C2 \u03B5\u03C6\u03B1\u03C1\u03BC\u03BF\u03B3\u03AD\u03C2, \u03B5\u03BD\u03CE \u03B7 \u03BB\u03B1\u03BC\u03C0\u03C1\u03CC\u03C4\u03B7\u03C4\u03AC \u03C4\u03BF\u03C5 \u03C4\u03BF \u03BA\u03AC\u03BD\u03B5\u03B9 \u03C4\u03BF\u03BD \u03C0\u03B9\u03BF \u03B3\u03BD\u03C9\u03C3\u03C4\u03CC \u03BA\u03B1\u03B9 \u03C0\u03B5\u03C1\u03B9\u03B6\u03AE\u03C4\u03B7\u03C4\u03BF \u03C0\u03BF\u03BB\u03CD\u03C4\u03B9\u03BC\u03BF \u03BB\u03AF\u03B8\u03BF. \u03A4\u03BF \u03B2\u03AC\u03C1\u03BF\u03C2 \u03C4\u03BF\u03C5 \u03BC\u03B5\u03C4\u03C1\u03AC\u03C4\u03B1\u03B9 \u03C3\u03B5 \u03BA\u03B1\u03C1\u03AC\u03C4\u03B9\u03B1 (1 \u03BA\u03B1\u03C1\u03AC\u03C4\u03B9 = 200 \u03C7\u03B9\u03BB\u03B9\u03BF\u03C3\u03C4\u03AC \u03C4\u03BF\u03C5 \u03B3\u03C1\u03B1\u03BC\u03BC\u03B1\u03C1\u03AF\u03BF\u03C5)."@el . . "Diamant"@de . "\u0394\u03B9\u03B1\u03BC\u03AC\u03BD\u03C4\u03B9"@el . . . . "Diament \u2013 bardzo rzadki minera\u0142 z gromady pierwiastk\u00F3w rodzimych. Nazwa pochodzi od stgr. \u1F00\u03B4\u03AC\u03BC\u03B1\u03C2 adamas (dope\u0142niacz \u1F00\u03B4\u03AC\u03BC\u03B1\u03BD\u03C4\u03BF\u03C2 adamantos, \u0142ac. diamentum) \u201Bniepokonany, niezniszczalny\u2019 i nawi\u0105zuje do jego wyj\u0105tkowej twardo\u015Bci. Jest najtwardsz\u0105 znan\u0105 substancj\u0105 wyst\u0119puj\u0105c\u0105 w przyrodzie. Antoine Lavoisier po raz pierwszy spali\u0142 diament pod szklanym kloszem, u\u017Cywaj\u0105c promieni s\u0142onecznych skupionych soczewk\u0105. Udowodni\u0142 w ten spos\u00F3b, \u017Ce diament to czysty w\u0119giel."@pl . . . "En la mineralog\u00EDa el diamante es un al\u00F3tropo del carbono en el que los \u00E1tomos de carbono est\u00E1n dispuestos en una variante de la estructura cristalina c\u00FAbica centrada en la cara denominada. El diamante es la segunda forma m\u00E1s estable de carbono, despu\u00E9s del grafito; sin embargo, la tasa de conversi\u00F3n de diamante a grafito es despreciable a condiciones ambientales. El diamante tiene renombre espec\u00EDficamente como un material con caracter\u00EDsticas f\u00EDsicas superlativas, muchas de las cuales derivan del fuerte enlace covalente entre sus \u00E1tomos. En particular, el diamante tiene la m\u00E1s alta dureza y conductividad t\u00E9rmica de todos los materiales conocidos por el ser humano. Estas propiedades determinan que la aplicaci\u00F3n industrial principal del diamante sea en herramientas de corte y de pulido adem\u00E1s de otras aplicaciones. El diamante es uno de los minerales con m\u00E1s valor del mundo por sus caracter\u00EDsticas f\u00EDsicas y \u00F3pticas. Debido a su estructura cristalina extremadamente r\u00EDgida, puede ser contaminada por pocos tipos de impurezas, como el boro y el nitr\u00F3geno. Combinado con su gran transparencia (correspondiente a una amplia banda prohibida de 5,5 eV), esto resulta en la apariencia clara e incolora de la mayor\u00EDa de diamantes naturales. Algunas peque\u00F1as cantidades de defectos o impurezas (aproximadamente una parte por mill\u00F3n) inducen un color de diamante azul (boro), amarillo (nitr\u00F3geno), marr\u00F3n (defectos cristalinos), verde, violeta, rosado, negro, naranja o rojo. El diamante tambi\u00E9n tiene una dispersi\u00F3n refractiva relativamente alta, esto es, la propiedad de dispersar luz de diferentes colores, lo que resulta en su lustre caracter\u00EDstico. Sus propiedades \u00F3pticas y mec\u00E1nicas excelentes, combinadas con una mercadotecnia eficiente, hacen que el diamante sea la gema m\u00E1s popular. La mayor\u00EDa de diamantes naturales se forman en condiciones de presi\u00F3n y temperatura extremas existentes a profundidades de 140 km a 190 km en el manto terrestre. Los minerales que contienen carbono proveen la fuente de carbono, y el crecimiento tiene lugar en per\u00EDodos de 1 a 3,3 mil millones de a\u00F1os, lo que corresponde, aproximadamente, al 25 % a 75 % de la edad de la Tierra. Los diamantes son trasladados cerca de la superficie de la Tierra a trav\u00E9s de erupciones volc\u00E1nicas profundas por el magma, que se enfr\u00EDa en rocas \u00EDgneas conocidas como kimberlitas y lamproitas. Los diamantes tambi\u00E9n pueden ser producidos sint\u00E9ticamente en un proceso de alta presi\u00F3n y alta temperatura que simula aproximadamente las condiciones en el manto de la Tierra. Una alternativa, y t\u00E9cnica completamente diferente, es la deposici\u00F3n qu\u00EDmica de vapor. Algunos materiales distintos al diamante, como la zirconia c\u00FAbica y carburo de silicio son denominados frecuentemente simulantes de diamantes, por semejarse al diamante en apariencia y muchas propiedades. Se han desarrollado t\u00E9cnicas gemol\u00F3gicas especiales para distinguir los naturales de los diamantes sint\u00E9ticos y los simulantes de diamantes."@es . . "Diamant"@sv . . . . "Typically yellow, brown, or gray to colorless. Less often blue, green, black, translucent white, pink, violet, orange, purple, and red."@en . "Diamant"@nl . . "Spinel law common"@en . "\u30C0\u30A4\u30E4\u30E2\u30F3\u30C9\uFF08\u82F1: diamond [\u02C8da\u026A\u0259m\u0259nd]\uFF09\u306F\u3001\u70AD\u7D20\u306E\u307F\u304B\u3089\u306A\u308B\u9271\u7269\u3002\u70AD\u7D20\u306E\u540C\u7D20\u4F53\u306E\u4E00\u7A2E\u3067\u3042\u308A\u3001\u5929\u7136\u306B\u5B58\u5728\u3059\u308B\u7269\u8CEA\u306E\u3046\u3061\u3067\u6700\u3082\u786C\u5EA6\u304C\u9AD8\u304F\u3001\u4E00\u822C\u7684\u306B\u7121\u8272\u900F\u660E\u3067\u7F8E\u3057\u3044\u5149\u6CA2\u3092\u3082\u3064\u3002\u30C0\u30A4\u30E4\u3068\u3082\u7565\u3055\u308C\u308B\u3002\u548C\u540D\u306F\u300C\u91D1\u525B\u77F3\uFF08\u3053\u3093\u3054\u3046\u305B\u304D\uFF09\u300D\u3002"@ja . . . . . . . . "\u0410\u043B\u043C\u0430\u0301\u0437 (\u0432\u0456\u0434 \u0430\u0440\u0430\u0431. \u0623\u0644\u0645\u0627\u0633\u200E, alm\u0101s \u2014 \u043D\u0435\u0437\u0434\u043E\u043B\u0430\u043D\u043D\u0438\u0439, \u0430\u043D\u0433\u043B. diamond; \u043D\u0456\u043C. Diamant) \u2014 \u043C\u0456\u043D\u0435\u0440\u0430\u043B \u043A\u043B\u0430\u0441\u0443 \u0441\u0430\u043C\u043E\u0440\u043E\u0434\u043D\u0438\u0445 \u043D\u0435\u043C\u0435\u0442\u0430\u043B\u0456\u0432, \u0442\u0432\u0435\u0440\u0434\u0430 \u043A\u0440\u0438\u0441\u0442\u0430\u043B\u0456\u0447\u043D\u0430 \u0430\u043B\u043E\u0442\u0440\u043E\u043F\u043D\u0430 \u0432\u0438\u0434\u043E\u0437\u043C\u0456\u043D\u0430 \u043A\u0430\u0440\u0431\u043E\u043D\u0443 \u043A\u0443\u0431\u0456\u0447\u043D\u043E\u0457 \u0441\u0438\u043D\u0433\u043E\u043D\u0456\u0457."@uk . . . . . . . . . . . . . . "Diamond"@en . . . . . . . . "Diamanto estas unu el la naturaj alotropoj de karbono, tio estas solida formo de la elemento karbon kun siaj atomoj aran\u011Ditaj en kristala strukturo nome diamanta kubo. La \u0109efa alotropo estas grafito. \u011Ci estas gemo, uzata por juveloj. Je normaj kondi\u0109oj pri temperaturo kaj premo, alia solida formo de karbono konata kiel grafito estas la kemie stabila formo, sed diamantoj preska\u016D neniam konverti\u011Das al tio. Diamantoj havas la plej altajn malmolecon kaj termikan konduktivon de ajna natura materialo, propra\u0135oj kiuj estas uzataj en gravaj industriaj aplika\u0135oj kiel tran\u0109ado kaj polurado de iloj. Ili estas anka\u016D tialo ke diamantaj ambosaj \u0109eloj povas meti materialojn al premoj trovitaj profunde en la Tero."@eo . . "Diamant"@ga . . "260"^^ . . . . . . . "111"^^ . . 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"Diamant ist die kubische Modifikation des Kohlenstoffs und als nat\u00FCrlich vorkommender Feststoff ein Mineral aus der Mineralklasse der Elemente. Diamant bildet meist oktaederf\u00F6rmige Kristalle, oft mit gebogenen und streifigen Fl\u00E4chen. Weitere beobachtete Formen sind das Tetraeder, Dodekaeder und der W\u00FCrfel. Die Kristalle sind transparent, farblos oder durch Verunreinigungen (z. B. Stickstoff oder Bor) oder Kristallgitterdefekte gr\u00FCn, gelb, braun und seltener auch orange, blau, rosa, rot oder grau bis schwarz gef\u00E4rbt. Diamant ist der h\u00E4rteste nat\u00FCrliche Stoff. In der H\u00E4rteskala nach Mohs hat er die H\u00E4rte 10. Seine Schleifh\u00E4rte nach Rosiwal (auch absolute H\u00E4rte) ist 140-mal gr\u00F6\u00DFer als die des Korunds. Die H\u00E4rte des Diamanten ist allerdings in verschiedenen Kristallrichtungen unterschiedlich (Anisotropie). Dadurch ist es m\u00F6glich, Diamant mit Diamant zu schleifen. In dem dazu verwendeten Diamantpulver liegen die Kristalle in jeder Orientierung vor (statistische Isotropie), damit wirken immer auch die h\u00E4rtesten unter ihnen auf den zu schleifenden K\u00F6rper. Diamant ist optisch isotrop mit hoher Lichtbrechung und hoher Dispersion. Er zeigt Fluoreszenz und Phosphoreszenz und ist triboelektrisch. Er verf\u00FCgt \u00FCber die h\u00F6chste W\u00E4rmeleitf\u00E4higkeit aller bekannten Minerale. Das Gewicht einzelner Diamanten wird traditionell in Karat angegeben, einer Einheit, die exakt 0,2 Gramm entspricht (siehe Abschnitt \u201E\u201C). Ein unbehandelter, d. h. insbesondere ungeschliffener Diamant wird Rohdiamant genannt."@de . . . . "Il diamante \u00E8 una delle tante forme allotropiche in cui pu\u00F2 presentarsi il carbonio; in particolare il diamante \u00E8 costituito da un reticolo cristallino di atomi di carbonio disposti secondo una struttura particolare detta tetraedrica. Il diamante \u00E8 il pi\u00F9 duro dei minerali conosciuti e rappresenta uno dei pochi casi in cui un elemento (il carbonio) si rinviene in discreti quantitativi in natura allo stato puro."@it . "None"@en . . "The slightly misshapen octahedral shape of this rough diamond crystal in matrix is typical of the mineral. Its lustrous faces also indicate that this crystal is from a primary deposit."@en . . "Diamond"@en . . . . . . "\"A Contribution to the Understanding of Blue Fluorescence on the Appearance of Diamonds\""@en . . . . "Diamant ist die kubische Modifikation des Kohlenstoffs und als nat\u00FCrlich vorkommender Feststoff ein Mineral aus der Mineralklasse der Elemente. Diamant bildet meist oktaederf\u00F6rmige Kristalle, oft mit gebogenen und streifigen Fl\u00E4chen. Weitere beobachtete Formen sind das Tetraeder, Dodekaeder und der W\u00FCrfel. Die Kristalle sind transparent, farblos oder durch Verunreinigungen (z. B. Stickstoff oder Bor) oder Kristallgitterdefekte gr\u00FCn, gelb, braun und seltener auch orange, blau, rosa, rot oder grau bis schwarz gef\u00E4rbt."@de . . . . . . . . . . . . . "\u947D\u77F3\uFF08\u53E4\u5E0C\u814A\u8A9E\uFF1A\u1F00\u03B4\u03AC\u03BC\u03B1\u03C2\uFF1B\u6CD5\u8A9E\u3001\u5FB7\u8A9E\uFF1ADiamant\uFF1B\u82F1\u8A9E\uFF1ADiamond\uFF1B\u4FC4\u8A9E\uFF1A\u0410\u043B\u043C\u0430\u0437\uFF09\uFF0C\u70BA\u4E94\u7A2E\u6A1E\u8981\u5BF6\u77F3\u7684\u4E00\u7A2E\uFF0C\u5316\u5B66\u548C\u5DE5\u4E1A\u61C9\u7528\u4E2D\u79F0\u4E3A\u91D1\u525B\u77F3\u3002\u947D\u77F3\u662F\u78B3\u5143\u7D20\u7EC4\u6210\u7684\u7121\u8272\u6676\u4F53\uFF0C\u70BA\u76EE\u524D\u5DF2\u77E5\u786C\u5EA6\u50C5\u6B21\u65BC\u85CD\u7D72\u9EDB\u723E\u77F3\u7684\u5929\u7136\u7269\u8CEA\u3002"@zh . . . . . . . . . "Diamante"@it . . . . . . . . . . . . . . "no"@en . . . "En la mineralog\u00EDa el diamante es un al\u00F3tropo del carbono en el que los \u00E1tomos de carbono est\u00E1n dispuestos en una variante de la estructura cristalina c\u00FAbica centrada en la cara denominada. El diamante es la segunda forma m\u00E1s estable de carbono, despu\u00E9s del grafito; sin embargo, la tasa de conversi\u00F3n de diamante a grafito es despreciable a condiciones ambientales. El diamante tiene renombre espec\u00EDficamente como un material con caracter\u00EDsticas f\u00EDsicas superlativas, muchas de las cuales derivan del fuerte enlace covalente entre sus \u00E1tomos. En particular, el diamante tiene la m\u00E1s alta dureza y conductividad t\u00E9rmica de todos los materiales conocidos por el ser humano. Estas propiedades determinan que la aplicaci\u00F3n industrial principal del diamante sea en herramientas de corte y de pulido adem\u00E1s"@es . . . . "\u30C0\u30A4\u30E4\u30E2\u30F3\u30C9\uFF08\u82F1: diamond [\u02C8da\u026A\u0259m\u0259nd]\uFF09\u306F\u3001\u70AD\u7D20\u306E\u307F\u304B\u3089\u306A\u308B\u9271\u7269\u3002\u70AD\u7D20\u306E\u540C\u7D20\u4F53\u306E\u4E00\u7A2E\u3067\u3042\u308A\u3001\u5929\u7136\u306B\u5B58\u5728\u3059\u308B\u7269\u8CEA\u306E\u3046\u3061\u3067\u6700\u3082\u786C\u5EA6\u304C\u9AD8\u304F\u3001\u4E00\u822C\u7684\u306B\u7121\u8272\u900F\u660E\u3067\u7F8E\u3057\u3044\u5149\u6CA2\u3092\u3082\u3064\u3002\u30C0\u30A4\u30E4\u3068\u3082\u7565\u3055\u308C\u308B\u3002\u548C\u540D\u306F\u300C\u91D1\u525B\u77F3\uFF08\u3053\u3093\u3054\u3046\u305B\u304D\uFF09\u300D\u3002"@ja . . "Is cloch l\u00F3mhar \u00E9 diamant."@ga . . . . . . . . "Is cloch l\u00F3mhar \u00E9 diamant."@ga . . . . . . . . . . . . "A clear octahedral stone protrudes from a black rock."@en . . . . . . "\u30C0\u30A4\u30E4\u30E2\u30F3\u30C9"@ja . . . "\u03A4\u03BF \u03B4\u03B9\u03B1\u03BC\u03AC\u03BD\u03C4\u03B9 \u03AE \u03B1\u03B4\u03AC\u03BC\u03B1\u03BD\u03C4\u03B1\u03C2 (\u03B1\u03C1\u03C7. \u03B5\u03BB\u03BB\u03B7\u03BD. \u03B1\u03B4\u03AC\u03BC\u03B1\u03C2 = \u03B1\u03AE\u03C4\u03C4\u03B7\u03C4\u03BF\u03C2, \u03B1\u03BA\u03B1\u03C4\u03B1\u03BD\u03AF\u03BA\u03B7\u03C4\u03BF\u03C2, \u03BB\u03CC\u03B3\u03C9 \u03C4\u03B7\u03C2 \u03BC\u03B5\u03B3\u03AC\u03BB\u03B7\u03C2 \u03C3\u03BA\u03BB\u03B7\u03C1\u03CC\u03C4\u03B7\u03C4\u03AC\u03C2 \u03C4\u03BF\u03C5) \u03B5\u03AF\u03BD\u03B1\u03B9 \u03C0\u03B5\u03C1\u03AF\u03C6\u03B7\u03BC\u03BF \u03BF\u03C1\u03C5\u03BA\u03C4\u03CC \u03B3\u03B9\u03B1 \u03C4\u03B7\u03BD \u03B9\u03C3\u03C7\u03C5\u03C1\u03AE \u03BB\u03AC\u03BC\u03C8\u03B7 \u03C4\u03BF\u03C5 \u03BA\u03B1\u03B9 \u03C4\u03B7\u03BD \u03C0\u03BF\u03BB\u03CD \u03BC\u03B5\u03B3\u03AC\u03BB\u03B7 \u03C3\u03BA\u03BB\u03B7\u03C1\u03CC\u03C4\u03B7\u03C4\u03AC \u03C4\u03BF\u03C5, \u03BC\u03B5 \u03B9\u03B4\u03B9\u03B1\u03AF\u03C4\u03B5\u03C1\u03B7 \u03B4\u03B9\u03B5\u03B8\u03BD\u03AE \u03B5\u03BC\u03C0\u03BF\u03C1\u03B9\u03BA\u03AE \u03B1\u03BE\u03AF\u03B1. \u0391\u03BD\u03AE\u03BA\u03B5\u03B9 \u03C3\u03C4\u03B7\u03BD \u03BF\u03B9\u03BA\u03BF\u03B3\u03AD\u03BD\u03B5\u03B9\u03B1 \u03C4\u03C9\u03BD \u03B1\u03C5\u03C4\u03BF\u03C6\u03C5\u03CE\u03BD \u03C3\u03C4\u03BF\u03B9\u03C7\u03B5\u03AF\u03C9\u03BD. \u0391\u03C0\u03BF\u03C4\u03B5\u03BB\u03B5\u03AF\u03C4\u03B1\u03B9 \u03B1\u03C0\u03CC \u03BA\u03B1\u03B8\u03B1\u03C1\u03CC \u03AC\u03BD\u03B8\u03C1\u03B1\u03BA\u03B1. \u039B\u03CC\u03B3\u03C9 \u03C4\u03B7\u03C2 \u03C3\u03BA\u03BB\u03B7\u03C1\u03CC\u03C4\u03B7\u03C4\u03B1\u03C2 \u03B1\u03C5\u03C4\u03AE\u03C2 \u03C7\u03C1\u03B7\u03C3\u03B9\u03BC\u03BF\u03C0\u03BF\u03B9\u03B5\u03AF\u03C4\u03B1\u03B9 \u03C3\u03B5 \u03B2\u03B9\u03BF\u03BC\u03B7\u03C7\u03B1\u03BD\u03B9\u03BA\u03AD\u03C2 \u03B5\u03C6\u03B1\u03C1\u03BC\u03BF\u03B3\u03AD\u03C2, \u03B5\u03BD\u03CE \u03B7 \u03BB\u03B1\u03BC\u03C0\u03C1\u03CC\u03C4\u03B7\u03C4\u03AC \u03C4\u03BF\u03C5 \u03C4\u03BF \u03BA\u03AC\u03BD\u03B5\u03B9 \u03C4\u03BF\u03BD \u03C0\u03B9\u03BF \u03B3\u03BD\u03C9\u03C3\u03C4\u03CC \u03BA\u03B1\u03B9 \u03C0\u03B5\u03C1\u03B9\u03B6\u03AE\u03C4\u03B7\u03C4\u03BF \u03C0\u03BF\u03BB\u03CD\u03C4\u03B9\u03BC\u03BF \u03BB\u03AF\u03B8\u03BF. \u03A4\u03BF \u03B2\u03AC\u03C1\u03BF\u03C2 \u03C4\u03BF\u03C5 \u03BC\u03B5\u03C4\u03C1\u03AC\u03C4\u03B1\u03B9 \u03C3\u03B5 \u03BA\u03B1\u03C1\u03AC\u03C4\u03B9\u03B1 (1 \u03BA\u03B1\u03C1\u03AC\u03C4\u03B9 = 200 \u03C7\u03B9\u03BB\u03B9\u03BF\u03C3\u03C4\u03AC \u03C4\u03BF\u03C5 \u03B3\u03C1\u03B1\u03BC\u03BC\u03B1\u03C1\u03AF\u03BF\u03C5)."@el . . "Adamantine"@en . . . . "Diamante"@pt . . . . . . . . "Diamant"@fr . . . . . . "Diamant je t\u00E9m\u011B\u0159 nejtvrd\u0161\u00ED zn\u00E1m\u00FD p\u0159\u00EDrodn\u00ED miner\u00E1l (nerost) a jedna z nejtvrd\u0161\u00EDch l\u00E1tek v\u016Fbec (tvrd\u0161\u00ED jsou nap\u0159. fullerit, romboedrick\u00E1 modifikace diamantu \u010Di nanokrystalick\u00E1 forma diamantu \u2013 ADNR). Jedn\u00E1 se o krystalickou formu uhl\u00EDku C. Tvo\u0159\u00ED hlavn\u011B jednotliv\u00E9 krystaly oktaedrick\u00E9ho, dodekaedrick\u00E9ho nebo krychlov\u00E9ho vzhledu, typick\u00FD je vypoukl\u00FD a vz\u00E1cn\u011B a\u017E kulovit\u00FD tvar krystal\u016F. Diamanty \u010Dasto tvo\u0159\u00ED srostlice krystal\u016F. Pro pou\u017Eit\u00ED ve \u0161perku je nejobl\u00EDben\u011Bj\u0161\u00ED v\u00FDbrus naz\u00FDvan\u00FD briliant."@cs . . . . . . . . "C1C3CC5CC1CCC36C3CCCC6CC1C3"@en . . "Le diamant (/dja.m\u0251\u0303/) est l'allotrope de haute pression du carbone, m\u00E9tastable \u00E0 basses temp\u00E9rature et pression. Moins stable que le graphite et la lonsdal\u00E9ite qui sont les deux autres formes de cristallisation du carbone, sa renomm\u00E9e en tant que min\u00E9ral lui vient de ses propri\u00E9t\u00E9s physiques et des fortes liaisons covalentes entre ses atomes arrang\u00E9s selon un syst\u00E8me cristallin cubique. En particulier, le diamant est le mat\u00E9riau naturel le plus dur (avec l'indice maximal (10) sur l'\u00E9chelle de Mohs) et il poss\u00E8de une tr\u00E8s forte conductivit\u00E9 thermique. Ses propri\u00E9t\u00E9s font que le diamant trouve de nombreuses applications dans l'industrie comme outils de coupe et d'usinage, dans les sciences comme bistouris ou enclumes \u00E0 diamant et dans la joaillerie pour ses propri\u00E9t\u00E9s optiques."@fr . . "None"@en . . "604800.0"^^ . . . . . . . . "2.418"^^ . . "\u0410\u043B\u043C\u0430\u0437"@uk . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .