[{"data":1,"prerenderedAt":-1},["ShallowReactive",2],{"minerals:one:43298":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":22,"key_elements":11,"impurities":11,"cim":11,"ima_status":23,"ima_notes":11,"ima_history":11,"approval_year":25,"publication_year":11,"discovery_year":11,"strunz10ed1":26,"strunz10ed2":27,"strunz10ed3":28,"strunz10ed4":29,"dana8ed1":11,"dana8ed2":11,"dana8ed3":11,"dana8ed4":11,"csystem":30,"cclass":31,"spacegroup":11,"spacegroupset":32,"a":33,"b":34,"c":35,"alpha":11,"beta":11,"gamma":11,"aerror":36,"berror":11,"cerror":37,"alphaerror":11,"betaerror":11,"gammaerror":11,"va3":11,"z":11,"csmetamict":14,"commentcrystal":38,"twinning":11,"tranglide":11,"parting":11,"epitaxidescription":11,"morphology":11,"tlform":39,"hmin":40,"hmax":41,"hardtype":11,"vhnmin":11,"vhnmax":11,"vhnerror":11,"vhng":11,"vhns":11,"commenthard":42,"dmeas":11,"dmeas2":11,"dcalc":43,"dmeaserror":11,"dcalcerror":11,"commentdense":11,"lustre":11,"lustretype":44,"commentluster":11,"diapheny":45,"streak":11,"colour":46,"commentcolor":47,"colors":48,"streak_colors":11,"luminescence":11,"uv":11,"cleavage":51,"cleavagetype":52,"fracturetype":11,"tenacity":53,"commentbreak":11,"opticaltype":11,"opticalsign":11,"opticalalpha":11,"opticalalpha2":11,"opticalalphaerror":11,"opticalbeta":11,"opticalbeta2":11,"opticalbetaerror":11,"opticalgamma":11,"opticalgamma2":11,"opticalgammaerror":11,"opticalomega":11,"opticalomega2":11,"opticalomegaerror":11,"opticalepsilon":11,"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":11,"opticalpleochorismdesc":11,"opticalbirefringence":11,"opticalcomments":11,"opticalcolour":11,"opticalinternal":11,"opticaltropic":11,"opticalanisotropism":11,"opticalbireflectance":11,"opticalextinction":11,"opticalr":11,"specdispm":54,"ir":11,"electrical":11,"magnetism":11,"thermalbehaviour":11,"other":11,"industrial":11,"occurrence":55,"otheroccurrence":11,"type_specimen_store":56,"description_short":57,"aboutname":58,"rock_parent":11,"rock_parent2":11,"rock_root":9,"rock_bgs_code":11,"meteoritical_code":11,"updttime":59,"reviewed_at":11,"variety_of":11,"varieties":60,"group_members":61,"associates":73,"confused_with":74,"type_localities":75,"occurrence_total":82,"citations":83,"images":116,"structures":117,"synonyms":118,"language_names":122,"wikidata_qid":144,"texts":145},43298,"1:1:43298:6","a0dd7617-fca0-418e-bd60-2cceb2214b71","Mössbauerite","Msb",0,"mineral",null,43292,26,false,"Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>6\u003C\u002Fsub>O\u003Csub>4\u003C\u002Fsub>(OH)\u003Csub>8\u003C\u002Fsub>[CO\u003Csub>3\u003C\u002Fsub>]&middot;3H\u003Csub>2\u003C\u002Fsub>O","Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>6\u003C\u002Fsub>O\u003Csub>4\u003C\u002Fsub>(OH)\u003Csub>8\u003C\u002Fsub>(CO\u003Csub>3\u003C\u002Fsub>) &middot; 3H\u003Csub>2\u003C\u002Fsub>O",[18,19,20,21],"Fe","O","C","H",[18,19,20,21],[24],"APPROVED",2012,"4","F","L","05","Trigonal",10,"0","3.032","3.079","22.258",7,4,"Possible space group: P3İm1 and P3m1","As μm-scale platelets in gleys with restricted access to atmospheric O.",2,3,"Probably 2-3","2.950","Earthy","Opaque","Blue-green","Pure synthetic mössbauerite is orange in colour",[49,50],"blue","green","{0001} ideally","Perfect","sectile","Decomposes rapidly when exposed to air.","Intimately intergrown with trébeurdenite, was discovered in intertidal gleys from Mont Saint-Michel Bay, France.","Museum Victoria, Melbourne, Australia, registration number M52078","Hydrotalcite supergroup. It has a layered double hydroxide-type structure, in which brucite-like layers [Fe3+6O4(OH)8]2+ are intercalated with CO32- anions and water molecules. \r\nThe fully oxidized analogue of fougèrite and trébeurdenite, related to th...","Named after Professor Rudolf Ludwig Mössbauer (31 January 1929 Munich – 14 September 2011 Grünwald, Germany) who discovered the resonance of γ rays that bears his name, for which he was awarded the 1961 Nobel Prize in physics. Without this technique, the very existence of this mineral in gleysols and the true nature of the ‘green rust’ compounds could not be understood","2026-04-10 19:27:47",[],[62,68],{"id":63,"name":64,"entrytype":9,"csystem":30,"ima_formula":65,"mindat_formula":66,"hmin":11,"hmax":11,"dmeas":32,"dcalc":32,"primary_image_id":67},27543,"Fougèrite","Fe\u003Csup>2+\u003C\u002Fsup>\u003Csub>4\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>12\u003C\u002Fsub>(CO\u003Csub>3\u003C\u002Fsub>) &middot; 3H\u003Csub>2\u003C\u002Fsub>O","Fe\u003Csup>2+\u003C\u002Fsup>\u003Csub>4\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>12\u003C\u002Fsub>[CO\u003Csub>3\u003C\u002Fsub>]&middot;3H\u003Csub>2\u003C\u002Fsub>O",9316,{"id":69,"name":70,"entrytype":9,"csystem":30,"ima_formula":71,"mindat_formula":72,"hmin":11,"hmax":11,"dmeas":11,"dcalc":11,"primary_image_id":11},43293,"Trébeurdenite","Fe\u003Csup>2+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>4\u003C\u002Fsub>O\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>10\u003C\u002Fsub>(CO\u003Csub>3\u003C\u002Fsub>) &middot; 3H\u003Csub>2\u003C\u002Fsub>O","Fe\u003Csup>2+\u003C\u002Fsup>\u003Csub>2\u003C\u002Fsub>Fe\u003Csup>3+\u003C\u002Fsup>\u003Csub>4\u003C\u002Fsub>O\u003Csub>2\u003C\u002Fsub>(OH)\u003Csub>10\u003C\u002Fsub>CO\u003Csub>3\u003C\u002Fsub>·3H\u003Csub>2\u003C\u002Fsub>O",[],[],[76],{"id":77,"txt":78,"latitude":79,"longitude":80,"country":81},245177,"Mont Saint-Michel marshes, Le Mont-Saint-Michel, Avranches, Manche, Normandy, France",48.6224074,-1.5199046,"France",8,[84,88,92,96,100,105,109,113],{"id":85,"year":25,"html":86,"doi":87},16139234,"Génin, Jean-Marie R.; Guérin, O.; Herbillon, A. J.; Kuzmann, E.; Mills, S. J.; Morin, G.; Ona-Nguema, G.; Ruby, C.; Upadhyay, C. (2012) Redox topotactic reactions in Fe II −  III (oxy)hydroxycarbonate new minerals related to fougèrite in gleysols: “trébeurdenite and mössbauerite”. \u003Ci>Hyperfine Interactions\u003C\u002Fi>,  204 (1-3). 71-81 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1007\u002Fs10751-011-0500-8'>doi:10.1007\u002Fs10751-011-0500-8\u003C\u002Fa>","10.1007\u002Fs10751-011-0500-8",{"id":89,"year":25,"html":90,"doi":91},244281,"Mills, S. J.; Christy, A. G.; Génin, J.-M. R.; Kameda, T.; Colombo, F. (2012) Nomenclature of the hydrotalcite supergroup: natural layered double hydroxides. \u003Ci>Mineralogical Magazine\u003C\u002Fi>,  76 (5). 1289-1336 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1180\u002Fminmag.2012.076.5.10'>doi:10.1180\u002Fminmag.2012.076.5.10\u003C\u002Fa>","10.1180\u002Fminmag.2012.076.5.10",{"id":93,"year":94,"html":95,"doi":11},16139235,2013,"Génin, J.-M.R. (2013) From fougèrite to mössbauerite through trébeurdenite; redox reactions in gleysols and role of bacteria. Mössbauer Effect Reference Data Journal: 36(6): 113-160.",{"id":97,"year":94,"html":98,"doi":99},244368,"Williams, P. A., Hatert, F., Pasero, M., Mills, S. J. (2013) IMA Commission on New Minerals, Nomenclature and Classification. CNMNC Newsletter No. 15. \u003Ci>Mineralogical Magazine\u003C\u002Fi>,  77 (1) 1-12 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1180\u002Fminmag.2013.077.1.01'>doi:10.1180\u002Fminmag.2013.077.1.01\u003C\u002Fa>","10.1180\u002Fminmag.2013.077.1.01",{"id":101,"year":102,"html":103,"doi":104},244511,2014,"Génin, J.-M. R., Mills, S. J., Christy, A. G., Guérin, O., Herbillon, A. J., Kuzmann, E., Ona-Nguema, G., Ruby, C., Upadhyay, C. (2014) Mössbauerite, Fe\u003Csub>6\u003C\u002Fsub>\u003Csup>3+\u003C\u002Fsup>O\u003Csub>4\u003C\u002Fsub>(OH)\u003Csub>8\u003C\u002Fsub>[CO\u003Csub>3\u003C\u002Fsub>]·3H\u003Csub>2\u003C\u002Fsub>O, the fully oxidized ‘green rust’ mineral from Mont Saint-Michel Bay, France. \u003Ci>Mineralogical Magazine\u003C\u002Fi>,  78 (2) 447-465 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1180\u002Fminmag.2014.078.2.14'>doi:10.1180\u002Fminmag.2014.078.2.14\u003C\u002Fa> \u003Ca target='_blank' href='https:\u002F\u002Frruff.info\u002Frruff_1.0\u002Fuploads\u002FMM78_447.pdf' class='refpdflink'>\u003C\u002Fa>","10.1180\u002Fminmag.2014.078.2.14",{"id":106,"year":102,"html":107,"doi":108},16139236,"Génin, J.-M. R.; Christy, A.; Kuzmann, E.; Mills, S.; Ruby, C. (2014) Structure and occurrences of ≪ green rust ≫ related new minerals of the ≪ fougérite ≫ group, trébeurdenite and mössbauerite, belonging to the ≪ hydrotalcite ≫ supergroup; how Mössbauer spectroscopy helps XRD. \u003Ci>Hyperfine Interactions\u003C\u002Fi>,  226 (1-3). 459-482 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1007\u002Fs10751-014-1045-4'>doi:10.1007\u002Fs10751-014-1045-4\u003C\u002Fa>","10.1007\u002Fs10751-014-1045-4",{"id":110,"year":111,"html":112,"doi":11},16139237,2016,"Mills, S. J. (2016) To rust or not to rust : la trébeurdenite et la mössbauerite, deux nouvelles espèces de Bretagne et Normandie. Le Cahier des Micromonteurs: 131: 3–7.",{"id":114,"year":111,"html":115,"doi":11},16966132,"(2016) Mössbauerite. \u003Ci>Handbook of Mineralogy\u003C\u002Fi>. Mineralogical Society of America \u003Ca target='_blank' href='https:\u002F\u002Fhandbookofmineralogy.org\u002Fwp-content\u002Fuploads\u002F2022\u002F07\u002Fmo%CC%88ssbauerite.pdf' class='refpdflink'>\u003C\u002Fa>",[],[],[119,120,121],"IMA2012-049","Moessbauerite","Mössbaueriet",[123,127,132,136,140],{"lang":124,"names":125},"ca",[126],"mössbauerita",{"lang":128,"names":129},"de",[130,131],"IMA 2012-049","Mössbauerit",{"lang":133,"names":134},"eu",[135],"Mössbauerita",{"lang":137,"names":138},"it",[139],"mössbauerite",{"lang":141,"names":142},"ko",[143],"뫼스바우어라이트","Q19861044",{"history":11,"applications":11}]