[{"data":1,"prerenderedAt":-1},["ShallowReactive",2],{"minerals:one:2592":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":15,"elements":16,"sigelements":20,"key_elements":21,"impurities":11,"cim":22,"ima_status":23,"ima_notes":11,"ima_history":11,"approval_year":11,"publication_year":11,"discovery_year":26,"strunz10ed1":27,"strunz10ed2":28,"strunz10ed3":29,"strunz10ed4":30,"dana8ed1":31,"dana8ed2":32,"dana8ed3":33,"dana8ed4":33,"csystem":34,"cclass":35,"spacegroup":36,"spacegroupset":37,"a":38,"b":37,"c":39,"alpha":37,"beta":37,"gamma":37,"aerror":40,"berror":11,"cerror":41,"alphaerror":11,"betaerror":11,"gammaerror":11,"va3":11,"z":11,"csmetamict":14,"commentcrystal":42,"twinning":11,"tranglide":11,"parting":11,"epitaxidescription":11,"morphology":43,"tlform":11,"hmin":44,"hmax":44,"hardtype":11,"vhnmin":37,"vhnmax":37,"vhnerror":11,"vhng":11,"vhns":11,"commenthard":11,"dmeas":45,"dmeas2":45,"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":54,"luminescence":11,"uv":11,"cleavage":11,"cleavagetype":55,"fracturetype":56,"tenacity":57,"commentbreak":11,"opticaltype":11,"opticalsign":11,"opticalalpha":37,"opticalalpha2":37,"opticalalphaerror":11,"opticalbeta":37,"opticalbeta2":37,"opticalbetaerror":11,"opticalgamma":37,"opticalgamma2":37,"opticalgammaerror":11,"opticalomega":37,"opticalomega2":37,"opticalomegaerror":11,"opticalepsilon":37,"opticalepsilon2":37,"opticalepsilonerror":11,"opticaln":37,"opticaln2":37,"opticalnerror":11,"optical2vcalc":37,"optical2vcalc2":37,"optical2vcalcerror":11,"optical2vmeasured":37,"optical2vmeasured2":37,"optical2vmeasurederror":11,"rimin":11,"rimax":11,"opticaldispersion":11,"opticalpleochroism":58,"opticalpleochorismdesc":11,"opticalbirefringence":11,"opticalcomments":11,"opticalcolour":59,"opticalinternal":11,"opticaltropic":60,"opticalanisotropism":58,"opticalbireflectance":11,"opticalextinction":11,"opticalr":61,"specdispm":11,"ir":11,"electrical":11,"magnetism":11,"thermalbehaviour":11,"other":11,"industrial":11,"occurrence":11,"otheroccurrence":11,"type_specimen_store":11,"description_short":62,"aboutname":63,"rock_parent":11,"rock_parent2":11,"rock_root":9,"rock_bgs_code":11,"meteoritical_code":11,"updttime":64,"reviewed_at":11,"variety_of":11,"varieties":65,"group_members":66,"associates":78,"confused_with":79,"type_localities":87,"occurrence_total":92,"citations":93,"images":201,"structures":222,"synonyms":229,"language_names":239,"wikidata_qid":264,"texts":265},2592,"1:1:2592:4","9a036ba2-8f35-42d3-a8f0-3b7299155642","Matildite","Mtd",0,"mineral",null,36013,1174,false,"AgBiS\u003Csub>2\u003C\u002Fsub>",[17,18,19],"Ag","Bi","S",[17,18,19],[17,18],"5.2.17",[24,25],"APPROVED","GRANDFATHERED","1883","2","J","A","20","3","7","1","Trigonal",12,89,"0","4.0675","18.9570",3,13,"Space group and cell from Kolitsch et al. (2021). Originally assumed to have space group P-3m1. Note: Harris & Thorpe (1969) suggested a hexagonal cell with a = 8.12, c = 19.02 Å.","Rarely as indistinct prismatic crystals, striated [001]. Massive, granular.",2.5,"6.9","Metallic","Opaque","Light gray","Iron-black to gray",[51,52,53],"black","gray","white",[52],"None Observed","Irregular\u002FUneven","brittle","Weak","White","Anisotropic","(41.4,47.2) 400,\r\n(41.9,47.8) 420,\r\n(42.2,48.3) 440,\r\n(43.1,48.8) 460,\r\n(43.4,49.3) 480,\r\n(43.4,49.3) 500,\r\n(43.0,49.0) 520,\r\n(42.8,48.4) 540,\r\n(42.5,47.8) 560,\r\n(42.2,47.3) 580,\r\n(41.7,46.9) 600,\r\n(41.3,46.7) 620,\r\n(40.8,46.7) 640,\r\n(40.3,46.7) 660,\r\n(39.9,46.3) 680,\r\n(39.3,46.1) 700","Matildite Group.\r\n\r\nCorresponds to the low-temperature (beta) form of synthetic AgBiS2. The high-temperature (alpha) form is only stable above 195 +- 5°C (Wu, 1989).\r\n\r\nSolid solution between matildite and galena is complete above 215 +- 15°C; below th...","From the type locality, the Matilda Mine, near Morococha, Peru.","2026-04-22 12:57:47",[],[67,74],{"id":68,"name":69,"entrytype":9,"csystem":34,"ima_formula":70,"mindat_formula":70,"hmin":40,"hmax":71,"dmeas":37,"dcalc":72,"primary_image_id":73},706,"Bohdanowiczite","AgBiSe\u003Csub>2\u003C\u002Fsub>",3.5,"7.72",3546,{"id":75,"name":76,"entrytype":9,"csystem":34,"ima_formula":77,"mindat_formula":77,"hmin":44,"hmax":40,"dmeas":37,"dcalc":37,"primary_image_id":11},4205,"Volynskite","AgBiTe\u003Csub>2\u003C\u002Fsub>",[],[80],{"id":81,"name":82,"entrytype":9,"csystem":83,"ima_formula":84,"mindat_formula":84,"hmin":44,"hmax":85,"dmeas":37,"dcalc":86,"primary_image_id":11},3558,"Schapbachite","Isometric","Ag\u003Csub>0.4\u003C\u002Fsub>Pb\u003Csub>0.2\u003C\u002Fsub>Bi\u003Csub>0.4\u003C\u002Fsub>S",4,"7.05",[88],{"id":89,"txt":90,"latitude":11,"longitude":11,"country":91},15796,"Matilda Mine, Morococha District, Yauli Province, Junín, Peru","Peru",302,[94,97,101,105,109,113,117,121,125,129,134,139,143,147,151,155,160,164,168,172,177,181,186,191,196],{"id":95,"year":11,"html":96,"doi":11},15952120,"Kolitsch, Topa, D., Giester, G. (2021): Revisions of the crystal structures of matildite, AgBiS2, and christite, TlHgAsS3. Poster, MinPet 2021, Vienna, Austria, September 19-21, 2021; abstract in Mitt. Österr. Mineral. Ges. 167, 118.",{"id":98,"year":99,"html":100,"doi":11},16116476,1877,"Rammelsberg (1877) Zs. deutsche geol. Ges.: 29: 80.",{"id":102,"year":103,"html":104,"doi":11},16116477,1882,"Sandberger (1882): 1: 96 (as plenargyrite).",{"id":106,"year":107,"html":108,"doi":11},16116478,1883,"D'Achiardi, A. (1883) Matildite e scirmerite. I Metalli Loro Minerali e Miniere, Volume 1, Ulrico Hoepli (Milano): 136-137.",{"id":110,"year":111,"html":112,"doi":11},16116479,1886,"Genth, F.A. (1886) Contributions from the Laboratory of the University of Pennsylvania, No. 24. Proceedings of the American Philosophical Society: 23: 30-47. (as argentobismutite)",{"id":114,"year":115,"html":116,"doi":11},16116480,1936,"Ramdohr, P. (1936) Bleiglanz, Schapbachite, Matildite. Fortschritte der Mineralogie: 20: 56-57.",{"id":118,"year":119,"html":120,"doi":11},520561,1937,"Foshag, W.F. (1937) New mineral names. \u003Ci>American Mineralogist\u003C\u002Fi>,  22 (1). 70-72 \u003Ca target='_blank' href='http:\u002F\u002Fwww.minsocam.org\u002Fammin\u002FAM22\u002FAM22_70.pdf?reftype=.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":122,"year":123,"html":124,"doi":11},1118651,1944,"Palache, Charles, Berman, Harry, Frondel, Clifford (1944) \u003Ci>The System of Mineralogy\u003C\u002Fi> (7th ed.) Vol. 1 - Elements, Sulfides, Sulfosalts, Oxides. John Wiley and Sons, New York.",{"id":126,"year":127,"html":128,"doi":11},522111,1951,"Graham, A. R. (1951) Matildite, aramayoite, miargyrite. \u003Ci>American Mineralogist\u003C\u002Fi>,  36 (5-6) 436-449 \u003Ca target='_blank' href='http:\u002F\u002Fwww.minsocam.org\u002Fammin\u002FAM36\u002FAM36_436.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":130,"year":131,"html":132,"doi":133},16103468,1959,"Geller, S.; Wernick, J. H. (1959) Ternary semiconducting compounds with sodium chloride-like structure: AgSbSe\u003Csub>2\u003C\u002Fsub>, AgSbTe\u003Csub>2\u003C\u002Fsub>, AgBiS\u003Csub>2\u003C\u002Fsub>, AgBiSe\u003Csub>2\u003C\u002Fsub>. \u003Ci>Acta Crystallographica\u003C\u002Fi>,  12 (1). 46-54 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1107\u002Fs0365110x59000135'>doi:10.1107\u002Fs0365110x59000135\u003C\u002Fa>","10.1107\u002Fs0365110x59000135",{"id":135,"year":136,"html":137,"doi":138},9980866,1968,"Glatz, A. C.; Pinella, A. (1968) X-ray and neutron diffraction studies of the high-temperature β-phase of the AgBiSe2\u002FAgBiS2 system. \u003Ci>Journal of Materials Science\u003C\u002Fi>,  3 (5). 498-501 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1007\u002Fbf00549732'>doi:10.1007\u002Fbf00549732\u003C\u002Fa>","10.1007\u002Fbf00549732",{"id":140,"year":141,"html":142,"doi":11},16116483,1969,"Harris, D.C., Thorpe, R.I. (1969) New observations on matildite. Canadian Mineralogist: 9: 655-662.",{"id":144,"year":145,"html":146,"doi":11},16116484,1976,"Scott, J.D. (1976) A microprobe-homogeneous intergrowth of galena and matildite from the Nipissing mine, Cobalt, Ontario. The Canadian Mineralogist: 14: 182-184.",{"id":148,"year":149,"html":150,"doi":11},16116485,1989,"Wu, D. (1989) Stability of matildite (AgBiS\u003Csub>2\u003C\u002Fsub>) and Ag\u003Csub>2\u003C\u002Fsub>Bi\u003Csub>4\u003C\u002Fsub>S\u003Csub>7\u003C\u002Fsub> and phase relations in the system silver sulfide (Ag\u003Csub>2\u003C\u002Fsub>S)-bismuth sulfide (Bi\u003Csub>2\u003C\u002Fsub>S\u003Csub>3\u003C\u002Fsub>). Kuangwu Xuebao: 9(2): 126-131. (in Chinese)",{"id":152,"year":153,"html":154,"doi":11},529023,1991,"Bayliss, Peter (1991) Crystal chemistry and crystallography of some minerals in the tetradymite group. \u003Ci>American Mineralogist\u003C\u002Fi>,  76 (1-2) 257-265 \u003Ca target='_blank' href='http:\u002F\u002Fwww.minsocam.org\u002Fammin\u002FAM76\u002FAM76_257.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":156,"year":157,"html":158,"doi":159},241434,1998,"SHIMIZU, Masaaki, KATO, Akira, MATSUYAMA, Fumihiko (1998) Two Se-bearing Ag-Bi Sulphosalts, Benjaminite and Matildite from the Ikuno Deposits, Hyogo Prefecture, Japan -Au-Ag Mineralization in Polymetallic Zone. \u003Ci>Resource Geology\u003C\u002Fi>,  48 (2) 117-124 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1111\u002Fj.1751-3928.1998.tb00011.x'>doi:10.1111\u002Fj.1751-3928.1998.tb00011.x\u003C\u002Fa>","10.1111\u002Fj.1751-3928.1998.tb00011.x",{"id":161,"year":162,"html":163,"doi":11},16116487,1999,"Wang, N. (1999): An experimental study of some solid solutions in the system Ag\u003Csub>2\u003C\u002Fsub>S-PbS-Bi\u003Csub>2\u003C\u002Fsub>S\u003Csub>3\u003C\u002Fsub> at low temperatures. Neues Jahrbuch für Mineralogie, Monatshefte 1999, 223-240.",{"id":165,"year":166,"html":167,"doi":11},16693743,2003,"Ondruš, P., Veselovský, F., Gabašová, A., Hloušek, J., Šrein, V., Vavřín, I., Skála, R., Sejkora, J., Drábek, M. (2003) Primary minerals of the Jáchymov ore district. \u003Ci>Journal of the Czech Geological Society\u003C\u002Fi>,  48 (3-4) 19-147 \u003Ca target='_blank' href='http:\u002F\u002Fwww.jgeosci.org\u002Fcontent\u002FJCGS2003_3-4__ondrus2.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":169,"year":170,"html":171,"doi":11},16965871,2005,"(2005) Matildite. \u003Ci>Handbook of Mineralogy\u003C\u002Fi>. Mineralogical Society of America \u003Ca target='_blank' href='https:\u002F\u002Fwww.handbookofmineralogy.org\u002Fpdfs\u002Fmatildite.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":173,"year":174,"html":175,"doi":176},395907,2008,"Chutas, N. I., Kress, V. C., Ghiorso, M. S., Sack, R. O. (2008) A solution model for high-temperature PbS-AgSbS2-AgBiS2 galena. \u003Ci>American Mineralogist\u003C\u002Fi>,  93 (10) 1630-1640 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.2138\u002Fam.2008.2695'>doi:10.2138\u002Fam.2008.2695\u003C\u002Fa>","10.2138\u002Fam.2008.2695",{"id":178,"year":174,"html":179,"doi":180},149043,"Damian, Gheorghe, Ciobanu, Cristiana L., Cook, Nigel J., Damian, Floarea (2008) Bismuth sulphosalts from the galena-matildite series in the Cremenea vein, Şuior, Baia Mare district, Romania. \u003Ci>Neues Jahrbuch für Mineralogie - Abhandlungen\u003C\u002Fi>,  185 (2) 199-213 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1127\u002F0077-7757\u002F2008\u002F0118'>doi:10.1127\u002F0077-7757\u002F2008\u002F0118\u003C\u002Fa>","10.1127\u002F0077-7757\u002F2008\u002F0118",{"id":182,"year":183,"html":184,"doi":185},225224,2013,"Voronin, M. V.; Osadchii, E. G. (2013) Thermodynamic properties of silver and bismuth sulfosalt minerals, pavonite (AgBi\u003Csub>3\u003C\u002Fsub>S\u003Csub>5\u003C\u002Fsub>) and matildite (AgBiS\u003Csub>2\u003C\u002Fsub>) and implications for ore deposits. \u003Ci>Economic Geology\u003C\u002Fi>,  108 (5). 1203-1210 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.2113\u002Fecongeo.108.5.1203'>doi:10.2113\u002Fecongeo.108.5.1203\u003C\u002Fa>","10.2113\u002Fecongeo.108.5.1203",{"id":187,"year":188,"html":189,"doi":190},2909242,2015,"Nakamura, Masaru, Nakamura, Hiroaki, Ohsawa, Takeo, Imura, Masataka, Shimamura, Kiyoshi, Ohashi, Naoki (2015) AgBiS2 single crystal grown using slow cooling method and its characterization. \u003Ci>Journal of Crystal Growth\u003C\u002Fi>, 411. 1-3 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1016\u002Fj.jcrysgro.2014.10.042'>doi:10.1016\u002Fj.jcrysgro.2014.10.042\u003C\u002Fa>","10.1016\u002Fj.jcrysgro.2014.10.042",{"id":192,"year":193,"html":194,"doi":195},16985333,2017,"Mitra, Sunanda; Berardan, David (2017) Influence of the temperature and composition on the crystal structure of the AgBiSe\u003Csub>2\u003C\u002Fsub>‐AgBiS\u003Csub>2\u003C\u002Fsub> system. \u003Ci>Crystal Research and Technology\u003C\u002Fi>,  52 (6). 1700075 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1002\u002Fcrat.201700075'>doi:10.1002\u002Fcrat.201700075\u003C\u002Fa>","10.1002\u002Fcrat.201700075",{"id":197,"year":198,"html":199,"doi":200},15839878,2023,"Alexandre, Paul, Aisida, Moses (2023) On the matildite–bohdanowiczite solid-solution series. \u003Ci>Mineralogical Magazine\u003C\u002Fi>,  87 (2) 292-299 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1180\u002Fmgm.2023.4'>doi:10.1180\u002Fmgm.2023.4\u003C\u002Fa> \u003Ca target='_blank' href='https:\u002F\u002Fwww.cambridge.org\u002Fcore\u002Fservices\u002Faop-cambridge-core\u002Fcontent\u002Fview\u002F2319F8D8985F2E57D2DB3A50BA11DBD0\u002FS0026461X2300004Xa.pdf\u002Fon-the-matildite-bohdanowiczite-solid-solution-series.pdf' class='refpdflink'>\u003C\u002Fa>","10.1180\u002Fmgm.2023.4",[202,212],{"id":203,"source_url":204,"license_code":205,"credit_html":206,"title":207,"description":208,"author":209,"original_width":210,"original_height":211},15584,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=75940430","CC BY-SA 4.0","David Hospital, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=75940430\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Matildite.jpg","Outstanding sharp bronze crystals of the rare sulphide mineral matildite from the famous Clara mine (Wolfach, Black Forest, Baden-Württemberg, Germany).","David Hospital",657,667,{"id":213,"source_url":214,"license_code":215,"credit_html":216,"title":217,"description":218,"author":219,"original_width":220,"original_height":221},15587,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=118194310","CC BY-SA 2.0","Pacific Museum of Earth from Canada, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=118194310\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Matildite (48904682206).jpg","\u003Cp>Porviner Mine\n\u003C\u002Fp>\nSud Lipez, Bolivia","Pacific Museum of Earth from Canada",3838,5889,[223],{"id":224,"url":225,"label":226,"formula":227,"spacegroup":228,"year":131},8548,"\u002Fcif\u002F8548.cif","Geller 1959","Ag Bi S2","P -3 m 1",[230,231,232,233,234,235,236,237,238],"Argentobismutit","Argentobismutita","Argentobismutite","Matildiet","Morocochite","Peruvite","Plenargyrite","Wismuthbleierz","Wismutisches Silber",[240,244,248,251,254,257,260],{"lang":241,"names":242},"az",[243],"Matildit",{"lang":245,"names":246},"ca",[247],"Matildita",{"lang":249,"names":250},"de",[243],{"lang":252,"names":253},"es",[247],{"lang":255,"names":256},"eu",[247],{"lang":258,"names":259},"it",[7],{"lang":261,"names":262},"uk",[263],"Матильдит","Q408263",{"history":11,"applications":11}]