[{"data":1,"prerenderedAt":-1},["ShallowReactive",2],{"minerals:one:43882":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":11,"ima_formula":16,"elements":17,"sigelements":23,"key_elements":24,"impurities":25,"cim":11,"ima_status":26,"ima_notes":11,"ima_history":11,"approval_year":28,"publication_year":11,"discovery_year":11,"strunz10ed1":29,"strunz10ed2":30,"strunz10ed3":31,"strunz10ed4":32,"dana8ed1":33,"dana8ed2":33,"dana8ed3":33,"dana8ed4":33,"csystem":34,"cclass":35,"spacegroup":36,"spacegroupset":33,"a":37,"b":11,"c":38,"alpha":11,"beta":11,"gamma":11,"aerror":39,"berror":11,"cerror":39,"alphaerror":11,"betaerror":11,"gammaerror":11,"va3":11,"z":11,"csmetamict":14,"commentcrystal":40,"twinning":11,"tranglide":11,"parting":41,"epitaxidescription":11,"morphology":11,"tlform":42,"hmin":43,"hmax":43,"hardtype":43,"vhnmin":11,"vhnmax":11,"vhnerror":11,"vhng":11,"vhns":11,"commenthard":11,"dmeas":44,"dmeas2":44,"dcalc":45,"dmeaserror":11,"dcalcerror":11,"commentdense":11,"lustre":11,"lustretype":46,"commentluster":11,"diapheny":47,"streak":48,"colour":49,"commentcolor":11,"colors":50,"streak_colors":52,"luminescence":11,"uv":53,"cleavage":54,"cleavagetype":55,"fracturetype":56,"tenacity":57,"commentbreak":11,"opticaltype":58,"opticalsign":59,"opticalalpha":11,"opticalalpha2":11,"opticalalphaerror":11,"opticalbeta":11,"opticalbeta2":11,"opticalbetaerror":11,"opticalgamma":11,"opticalgamma2":11,"opticalgammaerror":11,"opticalomega":60,"opticalomega2":11,"opticalomegaerror":11,"opticalepsilon":60,"opticalepsilon2":11,"opticalepsilonerror":11,"opticaln":11,"opticaln2":11,"opticalnerror":11,"optical2vcalc":11,"optical2vcalc2":11,"optical2vcalcerror":11,"optical2vmeasured":11,"optical2vmeasured2":11,"optical2vmeasurederror":11,"rimin":11,"rimax":11,"opticaldispersion":11,"opticalpleochroism":61,"opticalpleochorismdesc":11,"opticalbirefringence":11,"opticalcomments":62,"opticalcolour":11,"opticalinternal":11,"opticaltropic":11,"opticalanisotropism":11,"opticalbireflectance":11,"opticalextinction":11,"opticalr":11,"specdispm":11,"ir":11,"electrical":11,"magnetism":11,"thermalbehaviour":11,"other":11,"industrial":11,"occurrence":63,"otheroccurrence":11,"type_specimen_store":64,"description_short":65,"aboutname":66,"rock_parent":11,"rock_parent2":11,"rock_root":9,"rock_bgs_code":11,"meteoritical_code":11,"updttime":67,"reviewed_at":11,"variety_of":11,"varieties":68,"group_members":69,"associates":178,"confused_with":179,"type_localities":181,"occurrence_total":188,"citations":189,"images":201,"structures":212,"synonyms":219,"language_names":222,"wikidata_qid":245,"texts":246},43882,"1:1:43882:9","cb6b8384-155e-4d71-969e-1cd6c867bcf5","Paratacamite-(Ni)","Pata-Ni",0,"mineral",null,39924,94,false,"Cu\u003Csub>3\u003C\u002Fsub>(Ni,Cu)(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","Cu\u003Csub>3\u003C\u002Fsub>(Ni,Cu)Cl\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>6\u003C\u002Fsub>",[18,19,20,21,22],"Cl","Cu","Ni","O","H",[18,19,20,21,22],[18,19,20],"(Co)",[27],"APPROVED",2013,"3","D","A","10c","0","Trigonal",10,80," 13.682"," 13.916",2,"Space group by analogy to paratacamite.","None","aggregates up to 2 mm in size of equant, rhombohedral crystals showing the forms {101}, {021} and {001}.",3,"3.70","3.735","Vitreous","Transparent","Light green","Dark green",[51],"green",[51],"none","\u003Cmi>{10_11}\u003C\u002Fmi>","Distinct\u002FGood","Irregular\u002FUneven","brittle","Uniaxial","-",">1.8","Non-pleochroic","Refractive indices greater than 1.80, but mineral reacts with RI fluids. Average is 1.81 from Gladstone Dale calculation.","Oxidation zone of a nickel sulfide deposit","Type material is deposited in the collections of  the Western Australian Museum, Welshpool, Western Australia, Australia, specimen number WAM M365.2003 \r\n","Substituted derivative of paratacamite. The Ni analogue of paratacamite and paratacamite-(Mg). One of two Cu-Ni chloride minerals known. Product of oxidation of pentlandite in saline environment.\r\n\r\nCompare droninoite, muonionalustaite; akaganeite and ...","Nickel rich analog of paratacamite.","2025-08-11 12:15:10",[],[70,80,86,91,98,105,111,117,122,129,137,143,151,156,164,172],{"id":71,"name":72,"entrytype":9,"csystem":73,"ima_formula":74,"mindat_formula":75,"hmin":43,"hmax":76,"dmeas":77,"dcalc":78,"primary_image_id":79},406,"Atacamite","Orthorhombic","Cu\u003Csub>2\u003C\u002Fsub>Cl(OH)\u003Csub>3\u003C\u002Fsub>","Cu\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>3\u003C\u002Fsub>Cl",3.5,"3.745","3.756",2232,{"id":81,"name":82,"entrytype":9,"csystem":83,"ima_formula":74,"mindat_formula":75,"hmin":11,"hmax":11,"dmeas":84,"dcalc":84,"primary_image_id":85},732,"Botallackite","Monoclinic","3.6",3700,{"id":87,"name":88,"entrytype":9,"csystem":83,"ima_formula":74,"mindat_formula":75,"hmin":43,"hmax":43,"dmeas":33,"dcalc":89,"primary_image_id":90},1065,"Clinoatacamite","3.77",5813,{"id":92,"name":93,"entrytype":9,"csystem":34,"ima_formula":94,"mindat_formula":95,"hmin":43,"hmax":43,"dmeas":33,"dcalc":96,"primary_image_id":97},31405,"Gillardite","Cu\u003Csub>3\u003C\u002Fsub>NiCl\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>6\u003C\u002Fsub>","Cu\u003Csub>3\u003C\u002Fsub>Ni(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.76",9885,{"id":99,"name":100,"entrytype":9,"csystem":34,"ima_formula":101,"mindat_formula":101,"hmin":39,"hmax":39,"dmeas":102,"dcalc":103,"primary_image_id":104},31500,"Haydeeite","Cu\u003Csub>3\u003C\u002Fsub>Mg(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.27","3.24",10976,{"id":106,"name":107,"entrytype":9,"csystem":34,"ima_formula":108,"mindat_formula":108,"hmin":43,"hmax":76,"dmeas":109,"dcalc":96,"primary_image_id":110},26600,"Herbertsmithite","Cu\u003Csub>3\u003C\u002Fsub>Zn(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.85",11192,{"id":112,"name":113,"entrytype":9,"csystem":73,"ima_formula":114,"mindat_formula":114,"hmin":11,"hmax":11,"dmeas":33,"dcalc":115,"primary_image_id":116},1896,"Hibbingite","Fe\u003Csup>2+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>3\u003C\u002Fsub>Cl","3.04",11378,{"id":118,"name":119,"entrytype":9,"csystem":83,"ima_formula":120,"mindat_formula":120,"hmin":11,"hmax":11,"dmeas":11,"dcalc":121,"primary_image_id":11},45980,"Iyoite","MnCuCl(OH)\u003Csub>3\u003C\u002Fsub>","3.22",{"id":123,"name":124,"entrytype":9,"csystem":34,"ima_formula":108,"mindat_formula":108,"hmin":125,"hmax":125,"dmeas":126,"dcalc":127,"primary_image_id":128},27446,"Kapellasite",4,"3.55","3.62",12960,{"id":130,"name":131,"entrytype":9,"csystem":73,"ima_formula":132,"mindat_formula":133,"hmin":76,"hmax":76,"dmeas":134,"dcalc":135,"primary_image_id":136},2183,"Kempite","Mn\u003Csup>2+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>Cl(OH)\u003Csub>3\u003C\u002Fsub>","Mn\u003Csup>2+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>3\u003C\u002Fsub>Cl","~2.94","2.96",13118,{"id":138,"name":139,"entrytype":9,"csystem":34,"ima_formula":140,"mindat_formula":140,"hmin":11,"hmax":11,"dmeas":141,"dcalc":142,"primary_image_id":11},50347,"Kuliginite","Fe\u003Csub>3\u003C\u002Fsub>Mg(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.13","3.001",{"id":144,"name":145,"entrytype":9,"csystem":34,"ima_formula":146,"mindat_formula":147,"hmin":43,"hmax":43,"dmeas":148,"dcalc":149,"primary_image_id":150},43877,"Leverettite","Cu\u003Csub>3\u003C\u002Fsub>CoCl\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>6\u003C\u002Fsub>","Cu\u003Csub>3\u003C\u002Fsub>Co(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.64","3.709 ",14437,{"id":152,"name":153,"entrytype":9,"csystem":34,"ima_formula":154,"mindat_formula":154,"hmin":11,"hmax":11,"dmeas":11,"dcalc":155,"primary_image_id":11},45977,"Misakiite","Cu\u003Csub>3\u003C\u002Fsub>Mn(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.42",{"id":157,"name":158,"entrytype":9,"csystem":34,"ima_formula":159,"mindat_formula":160,"hmin":43,"hmax":43,"dmeas":161,"dcalc":162,"primary_image_id":163},3115,"Paratacamite","Cu\u003Csub>3\u003C\u002Fsub>(Cu,Zn)Cl\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>6\u003C\u002Fsub>","Cu\u003Csub>3\u003C\u002Fsub>(Cu,Zn)(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.72","3.75",18728,{"id":165,"name":166,"entrytype":9,"csystem":34,"ima_formula":167,"mindat_formula":168,"hmin":43,"hmax":76,"dmeas":169,"dcalc":170,"primary_image_id":171},43878,"Paratacamite-(Mg)","Cu\u003Csub>3\u003C\u002Fsub>(Mg,Cu)Cl\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>6\u003C\u002Fsub>","Cu\u003Csub>3\u003C\u002Fsub>(Mg,Cu)(OH)\u003Csub>6\u003C\u002Fsub>Cl\u003Csub>2\u003C\u002Fsub>","3.50","3.551",18733,{"id":173,"name":174,"entrytype":9,"csystem":34,"ima_formula":175,"mindat_formula":101,"hmin":43,"hmax":76,"dmeas":11,"dcalc":176,"primary_image_id":177},45964,"Tondiite","Cu\u003Csub>3\u003C\u002Fsub>MgCl\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>6\u003C\u002Fsub>","3.503",24354,[],[180],{"id":92,"name":93,"entrytype":9,"csystem":34,"ima_formula":94,"mindat_formula":95,"hmin":43,"hmax":43,"dmeas":33,"dcalc":96,"primary_image_id":97},[182],{"id":183,"txt":184,"latitude":185,"longitude":186,"country":187},219,"Carr Boyd Rocks Ni mine, Menangina Station, Menzies Shire, Western Australia, Australia",-30.0667921,121.6269043,"Australia",1,[190,193,197],{"id":191,"year":28,"html":192,"doi":11},15933581,"Sciberras, Matthew J., Leverett, Peter, Williams, Peter A., Hibbs, David E., Downes, Peter J., Welch, Mark D., Kampf, Anthony R. (2013) Paratacamite-(Ni): Cu3(Ni,Cu)Cl2(OH)6, a new mineral from the Carr Boyd Rocks mine, Western Australia. \u003Ci>Australian Journal of Mineralogy,\u003C\u002Fi>,  17. 39-44",{"id":194,"year":28,"html":195,"doi":196},244434,"Williams, P. A., Hatert, F., Pasero, M., Mills, S. J. (2013) New minerals and nomenclature modifications approved in 2013. CNMNC Newsletter No 16. \u003Ci>Mineralogical Magazine\u003C\u002Fi>,  77 (6) 2695-2709 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1180\u002Fminmag.2013.077.6.01'>doi:10.1180\u002Fminmag.2013.077.6.01\u003C\u002Fa>","10.1180\u002Fminmag.2013.077.6.01",{"id":198,"year":199,"html":200,"doi":11},16966567,2016,"(2016) Paratacamite-(Ni). \u003Ci>Handbook of Mineralogy\u003C\u002Fi>. Mineralogical Society of America \u003Ca target='_blank' href='https:\u002F\u002Fwww.handbookofmineralogy.org\u002Fpdfs\u002Fparatacamite-Ni.pdf' class='refpdflink'>\u003C\u002Fa>",[202],{"id":203,"source_url":204,"license_code":205,"credit_html":206,"title":207,"description":208,"author":209,"original_width":210,"original_height":211},10059,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=78180710","CC BY-SA 4.0","David Hospital, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=78180710\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Paratacamite-(Ni).jpg","Outstanding dark green crystals of the very rare mineral paratacamite-(Ni) (IMA 2013-013) from the type and only known locality worldwide: Carr Boyd Ni Mine, Goongarrie, Western Australia, Australia. Associated minerals are the also rare nickel minerals hydrohonessite (yellow crystalline crust) and glaukosphaerite (green globules).\nThree very rare and aesthetic nickel minerals in a single specimen !","David Hospital",683,667,[213],{"id":214,"url":215,"label":216,"formula":217,"spacegroup":218,"year":28},10424,"\u002Fcif\u002F10424.cif","Sciberras 2013","Ni.71 Cu3.27 Co.02 Cl2 O6 H6","R -3",[220,221],"IMA2013-013","Paratacamiet-(Ni)",[223,228,233,237,241],{"lang":224,"names":225},"ca",[226,227],"Paratacamita-","paratacamita-(Ni)",{"lang":229,"names":230},"de",[231,232],"IMA 2013-013","Paratacamit-(Ni)",{"lang":234,"names":235},"eu",[226,236],"Paratacamita-(Ni)",{"lang":238,"names":239},"it",[240],"paratacamite-(Ni)",{"lang":242,"names":243},"sl",[231,244],"paratakamit-(Ni)","Q19861151",{"history":11,"applications":11}]