[{"data":1,"prerenderedAt":-1},["ShallowReactive",2],{"minerals:one:53137":3},{"id":4,"longid":5,"guid":6,"name":7,"shortcode_ima":8,"entrytype":9,"entrytype_text":10,"varietyof":11,"synid":11,"polytypeof":11,"groupid":12,"weighting":13,"nolocadd":14,"blacklisted":14,"mindat_formula":15,"mindat_formula_note":16,"ima_formula":17,"elements":18,"sigelements":26,"key_elements":11,"impurities":11,"cim":11,"ima_status":27,"ima_notes":11,"ima_history":11,"approval_year":29,"publication_year":30,"discovery_year":11,"strunz10ed1":31,"strunz10ed2":32,"strunz10ed3":33,"strunz10ed4":34,"dana8ed1":11,"dana8ed2":11,"dana8ed3":11,"dana8ed4":11,"csystem":35,"cclass":36,"spacegroup":37,"spacegroupset":38,"a":39,"b":11,"c":40,"alpha":11,"beta":11,"gamma":11,"aerror":41,"berror":11,"cerror":42,"alphaerror":11,"betaerror":11,"gammaerror":11,"va3":11,"z":43,"csmetamict":14,"commentcrystal":11,"twinning":11,"tranglide":11,"parting":44,"epitaxidescription":11,"morphology":45,"tlform":46,"hmin":47,"hmax":47,"hardtype":11,"vhnmin":11,"vhnmax":11,"vhnerror":11,"vhng":11,"vhns":11,"commenthard":11,"dmeas":48,"dmeas2":48,"dcalc":49,"dmeaserror":43,"dcalcerror":11,"commentdense":11,"lustre":11,"lustretype":11,"commentluster":11,"diapheny":50,"streak":11,"colour":51,"commentcolor":11,"colors":52,"streak_colors":11,"luminescence":11,"uv":57,"cleavage":11,"cleavagetype":58,"fracturetype":59,"tenacity":60,"commentbreak":11,"opticaltype":61,"opticalsign":62,"opticalalpha":11,"opticalalpha2":11,"opticalalphaerror":11,"opticalbeta":11,"opticalbeta2":11,"opticalbetaerror":11,"opticalgamma":11,"opticalgamma2":11,"opticalgammaerror":11,"opticalomega":63,"opticalomega2":11,"opticalomegaerror":64,"opticalepsilon":65,"opticalepsilon2":11,"opticalepsilonerror":64,"opticaln":11,"opticaln2":11,"opticalnerror":11,"optical2vcalc":11,"optical2vcalc2":11,"optical2vcalcerror":11,"optical2vmeasured":11,"optical2vmeasured2":11,"optical2vmeasurederror":11,"rimin":66,"rimax":67,"opticaldispersion":11,"opticalpleochroism":68,"opticalpleochorismdesc":69,"opticalbirefringence":11,"opticalcomments":11,"opticalcolour":11,"opticalinternal":11,"opticaltropic":11,"opticalanisotropism":11,"opticalbireflectance":11,"opticalextinction":70,"opticalr":11,"specdispm":11,"ir":11,"electrical":11,"magnetism":11,"thermalbehaviour":11,"other":11,"industrial":11,"occurrence":71,"otheroccurrence":11,"type_specimen_store":72,"description_short":11,"aboutname":73,"rock_parent":11,"rock_parent2":11,"rock_root":9,"rock_bgs_code":11,"meteoritical_code":11,"updttime":74,"reviewed_at":11,"variety_of":11,"varieties":75,"group_members":76,"associates":150,"confused_with":151,"type_localities":152,"occurrence_total":43,"citations":159,"images":172,"structures":183,"synonyms":184,"language_names":187,"wikidata_qid":200,"texts":201},53137,"1:1:53137:5","d7b303b2-1327-47a9-9438-d1cd534b8f94","Milanriederite","Mlrd",0,"mineral",null,32107,52,false,"(Ca\u003Csub>18\u003C\u002Fsub>[REE])Fe\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Mg\u003Csub>4\u003C\u002Fsub>Al\u003Csub>4\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>](OH)(OH)\u003Csub>9\u003C\u002Fsub>","According to Mössbauer data, all iron in the mineral is trivalent.\r\n\r\nThe formula is a partial simplification of the full structural formula. The large (VII-IX)-coordinated (X4)\u003Csub>2\u003C\u002Fsub>(X3)\u003Csub>8\u003C\u002Fsub>(X2)\u003Csub>8\u003C\u002Fsub>(X1) sites are here combined (e.g. Ca\u003Csub>19\u003C\u002Fsub>) and are typically filled with Ca, although other large cations such as the REE may be present. The square-pyramidal Y1 site can host a variety of M\u003Csup>2+\u003C\u002Fsup> and M\u003Csup>3+\u003C\u002Fsup> ions and is the basis for the distinction of several species. The VI-coordinated Y2 site typically is filled with Al, whereas the also VI-coordinated Y3 site may contain Al, Mg, and other cations of similar charge and size. The tetrahedral T1 site is typically vacant but may contain B (less commonly Al); the trigonal T2 site is also typically vacant but may also contain B. Some of the (SiO\u003Csub>4\u003C\u002Fsub>) may be replaced by (H\u003Csub>4\u003C\u002Fsub>O\u003Csub>4\u003C\u002Fsub>), akin to the Si\u003Csup>4+\u003C\u002Fsup> ↔︎ 4H\u003Csup>+\u003C\u002Fsup> hydrogarnet substitution. Among the oxygen that are not part of the silica tetrahedra, there are eight \"O11\" that typically occur as OH, two \"O10\" that are typically O & OH or OH & OH (the latter arrangement notably when Y1 is an M\u003Csup>2+\u003C\u002Fsup> cation). There may also be up to three \"O12\" that in most vesuvianite-group minerals are absent (and are not included here), but may be present particularly when T1 is occupied.\r\n\r\nNote: The published formula by Chukanov \u003Cem>et al.\u003C\u002Fem> (2019) includes ∑(REE+Y) = 1.97 \u003Cem>apfu\u003C\u002Fem> (primarily in the X3 site), although this amount does not dominate the site and so might be disregarded when considering the end-member formula. However, the extra charge afforded by this REE inclusion appears necessary to provide charge balance for defining M\u003Csup>2+\u003C\u002Fsup>>M\u003Csup>3+\u003C\u002Fsup> in the Y3 site, as full hydrogenation of the \"O10\" and \"O11\" positions would be otherwise insufficient.\r\n\r\nTo address this inconsistency and to closer approximate the published analysis, one \u003Cem>apfu\u003C\u002Fem> of REE is included in the presented formula to maintain charge balance (although other charge-balancing mechanisms, such as the addition of B into the normally vacant T1 and\u002For T2 sites, may also be possible).","(Ca,REE)\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Mg,Al,Fe\u003Csup>3+\u003C\u002Fsup>)\u003Csub>8\u003C\u002Fsub>Si\u003Csub>18\u003C\u002Fsub>O\u003Csub>68\u003C\u002Fsub>(OH,O)\u003Csub>10\u003C\u002Fsub>",[19,20,21,22,23,24,25],"Al","Ca","Fe","Mg","Si","O","H",[19,20,21,22,23,24,25],[28],"APPROVED",2018,2019,"9","B","G","35","Tetragonal",27,186,"P4\u002Fnnc ","15.6578","11.8597",4,5,2,"None","Type material:\r\nThe major crystal form is {111} and the minor forms (observed on some crystals) are {001}, {110}, and {100}.","Dipyramidal crystals up to 3 mm across.",6,"3.53","3.547","Translucent","Dark brownish-red",[53,54,55,56],"red","brown","pink","colorless","Not fluorescent.","None Observed","Irregular\u002FUneven","brittle","Uniaxial","-","1.744",3,"1.737",1.737,1.744,"Visible","Brownish-pink (O) to nearly colourless (E).","Parallel","Hydrothermal and metasomatic replacement and fracture-filling of\r\ndolostones by polymineralic aggregates.","Collections of the Fersman Mineralogical Museum, Russian Academy of Sciences, Leninskiy Prospekt 18-2, Moscow 119071, Russia, registration number 5224\u002F1."," The mineral is named in honour of Czech mineralogist Professor Milan Rieder (b. 1940), in recognition to his contributions to mineralogy and his service to the international mineralogical community.","2025-08-11 12:15:21",[],[77,84,92,98,106,113,121,129,134,142],{"id":78,"name":79,"entrytype":9,"csystem":35,"ima_formula":80,"mindat_formula":81,"hmin":82,"hmax":82,"dmeas":83,"dcalc":11,"primary_image_id":11},47914,"Alumovesuvianite","Ca\u003Csub>19\u003C\u002Fsub>Al(Al\u003Csub>10\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)Si\u003Csub>18\u003C\u002Fsub>O\u003Csub>69\u003C\u002Fsub>(OH)\u003Csub>9\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>AlAl\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)(☐\u003Csub>4\u003C\u002Fsub>)☐[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>]O(OH)\u003Csub>9\u003C\u002Fsub>",6.5,"3.31",{"id":85,"name":86,"entrytype":9,"csystem":35,"ima_formula":87,"mindat_formula":88,"hmin":82,"hmax":82,"dmeas":89,"dcalc":90,"primary_image_id":91},46798,"Cyprine","Ca\u003Csub>19\u003C\u002Fsub>Cu\u003Csup>2+\u003C\u002Fsup>(Al,Mg)\u003Csub>12\u003C\u002Fsub>Si\u003Csub>18\u003C\u002Fsub>O\u003Csub>69\u003C\u002Fsub>(OH)\u003Csub>9\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>Cu\u003Csup>2+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>](OH)(OH)\u003Csub>9\u003C\u002Fsub>","3.40","3.41",29574,{"id":93,"name":94,"entrytype":9,"csystem":35,"ima_formula":95,"mindat_formula":96,"hmin":47,"hmax":47,"dmeas":97,"dcalc":89,"primary_image_id":11},25683,"Fluorvesuvianite","Ca\u003Csub>19\u003C\u002Fsub>(Al,Mg)\u003Csub>13\u003C\u002Fsub>(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>(Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>)\u003Csub>4\u003C\u002Fsub>O(F,OH)\u003Csub>9\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>]O(F,OH)\u003Csub>9\u003C\u002Fsub>","3.43",{"id":99,"name":100,"entrytype":9,"csystem":35,"ima_formula":101,"mindat_formula":102,"hmin":47,"hmax":103,"dmeas":104,"dcalc":105,"primary_image_id":11},52166,"Hongheite","Ca\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>2+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Fe\u003Csup>3+\u003C\u002Fsup>,Mg,Al)\u003Csub>8\u003C\u002Fsub>(◻,B)\u003Csub>4\u003C\u002Fsub>BSi\u003Csub>18\u003C\u002Fsub>O\u003Csub>69\u003C\u002Fsub>(O,OH)\u003Csub>9\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>2+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Fe\u003Csup>3+\u003C\u002Fsup>,Mg)\u003Csub>8\u003C\u002Fsub>(◻\u003Csub>4\u003C\u002Fsub>)B[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>]O(OH,O)\u003Csub>9\u003C\u002Fsub>",7,"3.446","3.423",{"id":107,"name":108,"entrytype":9,"csystem":35,"ima_formula":109,"mindat_formula":110,"hmin":47,"hmax":47,"dmeas":111,"dcalc":112,"primary_image_id":11},47594,"Magnesiovesuvianite","Ca\u003Csub>19\u003C\u002Fsub>Mg(Al\u003Csub>11\u003C\u002Fsub>Mg)Si\u003Csub>18\u003C\u002Fsub>O\u003Csub>69\u003C\u002Fsub>(OH)\u003Csub>9\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>MgAl\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>](OH)(OH)\u003Csub>9\u003C\u002Fsub>","3.30","3.35",{"id":114,"name":115,"entrytype":9,"csystem":35,"ima_formula":116,"mindat_formula":117,"hmin":118,"hmax":11,"dmeas":119,"dcalc":120,"primary_image_id":11},53139,"Manaevite-(Ce)","Ca\u003Csub>11\u003C\u002Fsub>(Ce,H\u003Csub>2\u003C\u002Fsub>O,Ca)\u003Csub>8\u003C\u002Fsub>Mg(Al,Fe)\u003Csub>4\u003C\u002Fsub>(Mg,Ti,Fe\u003Csup>3+\u003C\u002Fsup>)\u003Csub>8\u003C\u002Fsub>[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>8\u003C\u002Fsub>(H\u003Csub>4\u003C\u002Fsub>O\u003Csub>4\u003C\u002Fsub>)\u003Csub>2\u003C\u002Fsub>](OH)\u003Csub>9\u003C\u002Fsub>","(Ca\u003Csub>13\u003C\u002Fsub>Ce\u003Csub>4\u003C\u002Fsub>[H\u003Csub>2\u003C\u002Fsub>O]\u003Csub>2\u003C\u002Fsub>)Mg(Al\u003Csub>3\u003C\u002Fsub>Mg)(Mg\u003Csub>3\u003C\u002Fsub>Ti\u003Csub>3\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>8\u003C\u002Fsub>(H\u003Csub>4\u003C\u002Fsub>O\u003Csub>4\u003C\u002Fsub>)\u003Csub>2\u003C\u002Fsub>]O(OH)\u003Csub>9\u003C\u002Fsub>",4.5,"3.80","3.72",{"id":122,"name":123,"entrytype":9,"csystem":35,"ima_formula":124,"mindat_formula":125,"hmin":47,"hmax":103,"dmeas":126,"dcalc":127,"primary_image_id":128},11475,"Manganvesuvianite","Ca\u003Csub>19\u003C\u002Fsub>Mn\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>10\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>(Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>)\u003Csub>4\u003C\u002Fsub>O(OH)\u003Csub>9\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>Mn\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>]O(OH)\u003Csub>9\u003C\u002Fsub>","0","3.404",15383,{"id":130,"name":131,"entrytype":9,"csystem":35,"ima_formula":11,"mindat_formula":132,"hmin":11,"hmax":11,"dmeas":11,"dcalc":11,"primary_image_id":133},471108,"Modraite","Ca\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>2+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Fe\u003Csup>2+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>](OH)(OH)\u003Csub>9\u003C\u002Fsub>",16420,{"id":135,"name":136,"entrytype":9,"csystem":35,"ima_formula":137,"mindat_formula":138,"hmin":82,"hmax":82,"dmeas":139,"dcalc":140,"primary_image_id":141},4223,"Vesuvianite","(Ca,Na)\u003Csub>19\u003C\u002Fsub>(Al,Mg,Fe)\u003Csub>13\u003C\u002Fsub>(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>(Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>)\u003Csub>4\u003C\u002Fsub>(OH,F,O)\u003Csub>10\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Al\u003Csub>6\u003C\u002Fsub>Mg\u003Csub>2\u003C\u002Fsub>)(◻\u003Csub>4\u003C\u002Fsub>)◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>]O(OH)\u003Csub>9\u003C\u002Fsub>","3.32","3.42",6769,{"id":143,"name":144,"entrytype":9,"csystem":35,"ima_formula":145,"mindat_formula":146,"hmin":47,"hmax":47,"dmeas":147,"dcalc":148,"primary_image_id":149},7367,"Wiluite","Ca\u003Csub>19\u003C\u002Fsub>(Al,Mg)\u003Csub>13\u003C\u002Fsub>(B,◻,Al)\u003Csub>5\u003C\u002Fsub>(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>(Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>)\u003Csub>4\u003C\u002Fsub>(O,OH)\u003Csub>10\u003C\u002Fsub>","Ca\u003Csub>19\u003C\u002Fsub>MgAl\u003Csub>4\u003C\u002Fsub>(Al,Mg)\u003Csub>8\u003C\u002Fsub>(B,◻)\u003Csub>4\u003C\u002Fsub>◻[Si\u003Csub>2\u003C\u002Fsub>O\u003Csub>7\u003C\u002Fsub>]\u003Csub>4\u003C\u002Fsub>[(SiO\u003Csub>4\u003C\u002Fsub>)\u003Csub>10\u003C\u002Fsub>]O(O,OH)\u003Csub>9\u003C\u002Fsub>","3.36","3.358",30977,[],[],[153],{"id":154,"txt":155,"latitude":156,"longitude":157,"country":158},2427,"Kombat Mine, Kombat, Otavi Constituency, Otjozondjupa Region, Namibia",-19.708116,17.7032969,"Namibia",[160,164,168],{"id":161,"year":29,"html":162,"doi":163},16080084,"Hålenius, U., Hatert, F., Pasero, M., Mills, S. J. (2018) CNMNC Newsletter 45, New minerals and nomenclature modifications approved in 2018. \u003Ci>Mineralogical Magazine\u003C\u002Fi>,  82 (5) 1225-1232 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1180\u002Fmgm.2018.160'>doi:10.1180\u002Fmgm.2018.160\u003C\u002Fa>","10.1180\u002Fmgm.2018.160",{"id":165,"year":30,"html":166,"doi":167},129845,"Chukanov, Nikita V., Panikorovskii, Taras L., Goncharov, Alexey G., Pekov, Igor V., Belakovskiy, Dmitriy I., Britvin, Sergey N., Möckel, Steffen, Vozchikova, Svetlana A. (2019) Milanriederite, (Ca,REE)\u003Csub>19\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>Al\u003Csub>4\u003C\u002Fsub>(Mg,Al,Fe\u003Csup>3+\u003C\u002Fsup>)\u003Csub>8\u003C\u002Fsub>Si\u003Csub>18\u003C\u002Fsub>O\u003Csub>68\u003C\u002Fsub>(OH,O)\u003Csub>10\u003C\u002Fsub>, a new vesuvianite-group mineral from the Kombat Mine, Namibia. \u003Ci>European Journal of Mineralogy\u003C\u002Fi>,  31 (3) 637-646 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1127\u002Fejm\u002F2019\u002F0031-2856'>doi:10.1127\u002Fejm\u002F2019\u002F0031-2856\u003C\u002Fa> \u003Ca target='_blank' href='https:\u002F\u002Frruff.info\u002Frruff_1.0\u002Fuploads\u002FEJM31_637.pdf' class='refpdflink'>\u003C\u002Fa>","10.1127\u002Fejm\u002F2019\u002F0031-2856",{"id":169,"year":170,"html":171,"doi":11},16966035,2022,"(2022) Milanriederite. \u003Ci>Handbook of Mineralogy\u003C\u002Fi>. Mineralogical Society of America \u003Ca target='_blank' href='https:\u002F\u002Fhandbookofmineralogy.org\u002Fpdfs\u002FMilanriederite.pdf' class='refpdflink'>\u003C\u002Fa>",[173],{"id":174,"source_url":175,"license_code":176,"credit_html":177,"title":178,"description":179,"author":180,"original_width":181,"original_height":182},16258,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=81711870","CC BY-SA 4.0","David Hospital, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=81711870\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Milanriederite.jpg","Dark orange crystals of the extremely rare mineral milanriederite (IMA 2018-041) from the type and only known locality worldwide, the famous Kombat mine in Namibia, close to Tsumeb.","David Hospital",777,667,[],[185,186],"IMA2018-041","Milanriederiet",[188,192,197],{"lang":189,"names":190},"ca",[191],"milanriederita",{"lang":193,"names":194},"de",[195,196],"IMA 2018-041","Milanriederit",{"lang":198,"names":199},"eu",[191],"Q57802775",{"history":11,"applications":11}]