[{"data":1,"prerenderedAt":-1},["ShallowReactive",2],{"minerals:one:2887":3},{"id":4,"longid":5,"guid":6,"name":7,"shortcode_ima":8,"entrytype":9,"entrytype_text":10,"varietyof":11,"synid":11,"polytypeof":11,"groupid":11,"weighting":12,"nolocadd":13,"blacklisted":13,"mindat_formula":14,"mindat_formula_note":11,"ima_formula":15,"elements":16,"sigelements":21,"key_elements":11,"impurities":11,"cim":22,"ima_status":23,"ima_notes":11,"ima_history":11,"approval_year":11,"publication_year":26,"discovery_year":27,"strunz10ed1":28,"strunz10ed2":29,"strunz10ed3":30,"strunz10ed4":31,"dana8ed1":32,"dana8ed2":33,"dana8ed3":34,"dana8ed4":33,"csystem":35,"cclass":36,"spacegroup":37,"spacegroupset":38,"a":39,"b":40,"c":41,"alpha":42,"beta":42,"gamma":42,"aerror":11,"berror":11,"cerror":11,"alphaerror":11,"betaerror":11,"gammaerror":11,"va3":11,"z":43,"csmetamict":13,"commentcrystal":44,"twinning":11,"tranglide":11,"parting":11,"epitaxidescription":11,"morphology":45,"tlform":46,"hmin":47,"hmax":48,"hardtype":11,"vhnmin":42,"vhnmax":42,"vhnerror":11,"vhng":11,"vhns":11,"commenthard":11,"dmeas":49,"dmeas2":50,"dcalc":51,"dmeaserror":11,"dcalcerror":11,"commentdense":52,"lustre":53,"lustretype":54,"commentluster":11,"diapheny":55,"streak":56,"colour":57,"commentcolor":58,"colors":59,"streak_colors":64,"luminescence":11,"uv":65,"cleavage":66,"cleavagetype":67,"fracturetype":68,"tenacity":11,"commentbreak":11,"opticaltype":69,"opticalsign":70,"opticalalpha":71,"opticalalpha2":42,"opticalalphaerror":11,"opticalbeta":72,"opticalbeta2":42,"opticalbetaerror":11,"opticalgamma":73,"opticalgamma2":42,"opticalgammaerror":11,"opticalomega":42,"opticalomega2":42,"opticalomegaerror":11,"opticalepsilon":42,"opticalepsilon2":42,"opticalepsilonerror":11,"opticaln":42,"opticaln2":42,"opticalnerror":11,"optical2vcalc":74,"optical2vcalc2":42,"optical2vcalcerror":11,"optical2vmeasured":75,"optical2vmeasured2":42,"optical2vmeasurederror":11,"rimin":76,"rimax":77,"opticaldispersion":78,"opticalpleochroism":79,"opticalpleochorismdesc":11,"opticalbirefringence":80,"opticalcomments":11,"opticalcolour":11,"opticalinternal":11,"opticaltropic":11,"opticalanisotropism":11,"opticalbireflectance":11,"opticalextinction":81,"opticalr":11,"specdispm":11,"ir":11,"electrical":11,"magnetism":11,"thermalbehaviour":11,"other":82,"industrial":11,"occurrence":83,"otheroccurrence":84,"type_specimen_store":85,"description_short":86,"aboutname":87,"rock_parent":11,"rock_parent2":11,"rock_root":9,"rock_bgs_code":11,"meteoritical_code":11,"updttime":88,"reviewed_at":11,"variety_of":11,"varieties":89,"group_members":90,"associates":91,"confused_with":121,"type_localities":128,"occurrence_total":135,"citations":136,"images":240,"structures":275,"synonyms":291,"language_names":293,"wikidata_qid":323,"texts":324},2887,"1:1:2887:1","4e328634-9974-45b0-b23b-afc4a1be08ac","Newberyite","New",0,"mineral",null,499,false,"Mg(PO\u003Csub>3\u003C\u002Fsub>OH)&middot;3H\u003Csub>2\u003C\u002Fsub>O","Mg(PO\u003Csub>3\u003C\u002Fsub>OH) &middot; 3H\u003Csub>2\u003C\u002Fsub>O",[17,18,19,20],"Mg","O","P","H",[17,18,19,20],"19.3.17",[24,25],"APPROVED","GRANDFATHERED",1879,"1879","8","C","E","10","39","1","6","Orthorhombic",8,61,"Pbca ","10.203","10.685","10.018","0",16,"TMPM 32:187 (1983) structure","Crystals equi-dimentional, short prismatic [001]; commonly thin tabular {100}; also tabular on {010} or dipyramidal {111} (in artificial crystals).","1 inch (2.2 cm) square crystals in guano.",3,3.5,"2.10","2.11","2.12","Measured value on Mejillones material; 2.123 (artificial material)."," Vitreous","Dull","Translucent","White","Light gray to white or colorless, pale brown","Colorless in transmitted light.",[60,61,62,63],"white","gray","colorless","brown",[60],"Not fluorescent.","On {010}, perfect; on {001}, poor.","Perfect","Hackly","Biaxial","+","1.514","1.518","1.533","48","45",1.514,1.533,"relatively weak, r \u003C v, perceptible.","Non-pleochroic","0.019","X = a; Y = b; Z = c.","Very slightly soluble in cold water. Readily soluble in dilute HCl.","Bat guano cave deposit.","Bat guano deposits.","Muséum Nationale d’Histoire Naturelle, Paris, France, number 99.504.","Mn analogue ia manganonewberyite.\r\n\r\nMay occur as a decomposition product of struvite.","Named by Gustav vom Rath in 1879 in honor of James Cosmo Newbery [June 28, 1843 Leghorn (Livorno), Italy - May 1,1895 East St. Kilda, Victoria, Australia] of Melbourne, Australia who discovered the mineral. Newbery was an assistant to Josiah Cooke at Harvard University, where he graduated in 1864. In Australia, he was curator at the Industrial and Technological Museum and later was a chemical analyst at the Mines Department. He was also a consulting chemist and was influential in the eventual establishing of food safety laws in Australia.","2025-09-27 19:41:49",[],[],[92,102,112],{"id":93,"name":94,"entrytype":9,"csystem":95,"ima_formula":96,"mindat_formula":97,"hmin":98,"hmax":99,"dmeas":100,"dcalc":101,"primary_image_id":11},321,"Ardealite","Monoclinic","Ca\u003Csub>2\u003C\u002Fsub>(PO\u003Csub>3\u003C\u002Fsub>OH)(SO\u003Csub>4\u003C\u002Fsub>) &middot; 4H\u003Csub>2\u003C\u002Fsub>O","Ca\u003Csub>2\u003C\u002Fsub>(PO\u003Csub>3\u003C\u002Fsub>OH)(SO\u003Csub>4\u003C\u002Fsub>)&middot;4H\u003Csub>2\u003C\u002Fsub>O",1,1.5,"2.30","2.32",{"id":103,"name":104,"entrytype":9,"csystem":105,"ima_formula":106,"mindat_formula":107,"hmin":48,"hmax":108,"dmeas":109,"dcalc":110,"primary_image_id":111},2482,"Magnesite","Trigonal","Mg(CO\u003Csub>3\u003C\u002Fsub>)","MgCO\u003Csub>3\u003C\u002Fsub>",4.5,"2.98","3.01",15120,{"id":113,"name":114,"entrytype":9,"csystem":35,"ima_formula":115,"mindat_formula":116,"hmin":99,"hmax":117,"dmeas":118,"dcalc":119,"primary_image_id":120},3811,"Struvite","(NH\u003Csub>4\u003C\u002Fsub>)Mg(PO\u003Csub>4\u003C\u002Fsub>) &middot; 6H\u003Csub>2\u003C\u002Fsub>O","(NH\u003Csub>4\u003C\u002Fsub>)Mg(PO\u003Csub>4\u003C\u002Fsub>)&middot;6H\u003Csub>2\u003C\u002Fsub>O",2,"1.711","1.705",23110,[122],{"id":123,"name":124,"entrytype":9,"csystem":35,"ima_formula":11,"mindat_formula":125,"hmin":47,"hmax":11,"dmeas":126,"dcalc":127,"primary_image_id":11},471111,"Manganonewberyite","Mn(PO\u003Csub>3\u003C\u002Fsub>OH)(H\u003Csub>2\u003C\u002Fsub>O)\u003Csub>3\u003C\u002Fsub>","2.34","2.337",[129],{"id":130,"txt":131,"latitude":132,"longitude":133,"country":134},205,"Skipton Caves, Mount Widderin, Skipton, Corangamite Shire, Victoria, Australia",-37.7369727,143.3478382,"Australia",25,[137,140,143,147,151,155,159,164,168,172,176,180,184,189,194,199,203,207,212,217,221,226,230,235],{"id":138,"year":26,"html":139,"doi":11},16118418,"vom Rath, G. (1879) Note sur deux nouveaux phosphates du guano. Bulletin de la Société Minéralogique de France: 2: 79-82. (paper includes note by Des Cloizeaux, M.)",{"id":141,"year":26,"html":142,"doi":11},16118419,"vom Rath, G. (1879) Berichte Niederrheinische Gesellschaft für Natur und Heilkunde, Bonn: 36: 5.",{"id":144,"year":145,"html":146,"doi":11},16118420,1883,"Schmidt, A. (1883) Newberyit von Mejillones, Chile. Zeitschrift für Kristallographie-Crystalline Materials: 7(1-6): 26-35.",{"id":148,"year":149,"html":150,"doi":11},15951858,1887,"MacIvor R W E (1887) On Australian bat guano and some minerals occurring therein. The Chemical News 55, 215-216",{"id":152,"year":153,"html":154,"doi":11},16118422,1901,"Hoffmann, G.C. (1901) On some new mineral occurrences in Canada. American Journal of Science: Series 4: 11: 149-153.",{"id":156,"year":157,"html":158,"doi":11},16118423,1903,"de Schulten (1903) Bulletin de la Société française de Minéralogie: 26: 24, 95 (artif. mat.).",{"id":160,"year":161,"html":162,"doi":163},647767,1921,"Larsen, Esper S. (1921) The microscopic determination of the nonopaque minerals. \u003Ci>Bulletin\u003C\u002Fi> 679. US Geological Survey \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.3133\u002Fb679'>doi:10.3133\u002Fb679\u003C\u002Fa> \u003Ca target='_blank' href='https:\u002F\u002Fpubs.usgs.gov\u002Fbul\u002F0679\u002Freport.pdf' class='refpdflink'>\u003C\u002Fa>","10.3133\u002Fb679",{"id":165,"year":166,"html":167,"doi":11},16118425,1928,"Richards, G. (1928) Newberyite and other phosphates from Ascension Island. American Mineralogist: 13: 397-401.",{"id":169,"year":170,"html":171,"doi":11},16118426,1939,"Hägele and Machatschki (1939) Centralblatt für Mineralogie, Geologie und Paleontologie, Stuttgart: 297.",{"id":173,"year":174,"html":175,"doi":11},1118652,1951,"Palache, Charles; Berman, Harry; Frondel, Clifford (1951) \u003Ci>The System of Mineralogy\u003C\u002Fi> (7th ed.) Vol. 2 - Halides, Nitrates, Borates, Carbonates, Sulfates, Phosphates, Arsenates, Tungstates, Molybdates, Etc. John Wiley and Sons.",{"id":177,"year":178,"html":179,"doi":11},16118428,1961,"(1961): Neues Jahrbuch für Mineralogie - Monatshefte, 1961, 97.",{"id":181,"year":182,"html":183,"doi":11},524608,1966,"Cohen, Lewis H., Ribbe, Paul H. (1966) Magnesium phosphate mineral replacement at Mono Lake, California. \u003Ci>American Mineralogist\u003C\u002Fi>,  51 (11-12) 1755-1765 \u003Ca target='_blank' href='http:\u002F\u002Fwww.minsocam.org\u002Fammin\u002FAM51\u002FAM51_1755.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":185,"year":186,"html":187,"doi":188},625315,1967,"Sutor, D. J. (1967) The crystal and molecular structure of newberyite, MgHPO4.3H2O. \u003Ci>Acta Crystallographica\u003C\u002Fi>,  23 (3) 418-422 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1107\u002Fs0365110x67002889'>doi:10.1107\u002Fs0365110x67002889\u003C\u002Fa>","10.1107\u002Fs0365110x67002889",{"id":190,"year":191,"html":192,"doi":193},402112,1971,"Durif-Varambon, André (1971) MnHPO4 • 3H2O un isotype de la newberyite. \u003Ci>Bulletin de Minéralogie\u003C\u002Fi>,  94 (5). 556-557 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.3406\u002Fbulmi.1971.6624'>doi:10.3406\u002Fbulmi.1971.6624\u003C\u002Fa>","10.3406\u002Fbulmi.1971.6624",{"id":195,"year":196,"html":197,"doi":198},204346,1979,"Abbona, F.; Boistelle, R.; Haser, R. (1979) Hydrogen bonding in MgHPO\u003Csub>4\u003C\u002Fsub>.3H\u003Csub>2\u003C\u002Fsub>O (newberyite). \u003Ci>Acta Crystallographica Section B Structural Crystallography and Crystal Chemistry\u003C\u002Fi>,  35 (11). 2514-2518 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1107\u002Fs0567740879009791'>doi:10.1107\u002Fs0567740879009791\u003C\u002Fa>","10.1107\u002Fs0567740879009791",{"id":200,"year":201,"html":202,"doi":11},16118433,1981,"(1981): Zeitschrift für Kristallographie: 154, 249.",{"id":204,"year":201,"html":205,"doi":206},2752843,"Boistelle, R.; Abbona, F. (1981) Morphology, habit and growth of newberyite crystals (MgHPO4·3 H2O). \u003Ci>Journal of Crystal Growth\u003C\u002Fi>,  54 (2). 275-295 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1016\u002F0022-0248(81)90472-3'>doi:10.1016\u002F0022-0248(81)90472-3\u003C\u002Fa>","10.1016\u002F0022-0248(81)90472-3",{"id":208,"year":209,"html":210,"doi":211},2754903,1982,"Abbona, F., Lundager Madsen, H.E., Boistelle, R. (1982) Crystallization of two magnesium phosphates, struvite and newberyite: Effect of pH and concentration. \u003Ci>Journal of Crystal Growth\u003C\u002Fi>, 57 (1). 6-14 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1016\u002F0022-0248(82)90242-1'>doi:10.1016\u002F0022-0248(82)90242-1\u003C\u002Fa>","10.1016\u002F0022-0248(82)90242-1",{"id":213,"year":214,"html":215,"doi":216},7741794,1983,"Bartl, H.; Catti, M.; Joswig, W.; Ferraris, G. (1983) Investigation of the crystal structure of newberyite, MgHPO4·3H2O, by single crystal neutron diffraction. \u003Ci>TMPM Tschermaks Mineralogische und Petrographische Mitteilungen\u003C\u002Fi>,  32 (2-3). 187-194 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1007\u002Fbf01081109'>doi:10.1007\u002Fbf01081109\u003C\u002Fa>","10.1007\u002Fbf01081109",{"id":218,"year":219,"html":220,"doi":11},16118437,1985,"Abbona, F, Rinaudo, C. (1985) Autoepitaxial growth and twinning of newberyite crystals (MgHPO4·3H2O). Neues Jahrbuch für Mineralogie Monatshefte: 1985(11): 481-490.",{"id":222,"year":223,"html":224,"doi":225},16388168,2005,"Frost, Ray L., Weier, Matt L., Martens, Wayde N., Henry, Dermot A., Mills, Stuart J. (2005) Raman spectroscopy of newberyite, hannayite and struvite. \u003Ci>Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy\u003C\u002Fi>, 62 (1) 181-188 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1016\u002Fj.saa.2004.12.024'>doi:10.1016\u002Fj.saa.2004.12.024\u003C\u002Fa>","10.1016\u002Fj.saa.2004.12.024",{"id":227,"year":228,"html":229,"doi":11},16966266,2007,"(2007) Newberyite. \u003Ci>Handbook of Mineralogy\u003C\u002Fi>. Mineralogical Society of America \u003Ca target='_blank' href='https:\u002F\u002Fwww.handbookofmineralogy.org\u002Fpdfs\u002Fnewberyite.pdf' class='refpdflink'>\u003C\u002Fa>",{"id":231,"year":232,"html":233,"doi":234},16391916,2011,"Frost, Ray L., Palmer, Sara J., Pogson, Ross E. (2011) Raman spectroscopy of newberyite Mg(PO3OH)·3H2O: A cave mineral. \u003Ci>Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy\u003C\u002Fi>, 79 (5) 1149-1153 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1016\u002Fj.saa.2011.04.035'>doi:10.1016\u002Fj.saa.2011.04.035\u003C\u002Fa>","10.1016\u002Fj.saa.2011.04.035",{"id":236,"year":237,"html":238,"doi":239},16448861,2012,"Frost, Ray L.; Palmer, Sara J.; Pogson, Ross E. (2012) Thermal stability of newberyite Mg(PO3OH)·3H2O. \u003Ci>Journal of Thermal Analysis and Calorimetry\u003C\u002Fi>,  107 (3). 1143-1146 \u003Ca target='_blank' href='https:\u002F\u002Fdoi.org\u002F10.1007\u002Fs10973-011-1593-7'>doi:10.1007\u002Fs10973-011-1593-7\u003C\u002Fa>","10.1007\u002Fs10973-011-1593-7",[241,251,259,265],{"id":242,"source_url":243,"license_code":244,"credit_html":245,"title":246,"description":247,"author":248,"original_width":249,"original_height":250},17599,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=10126589","CC BY-SA 3.0","Robert M. Lavinsky, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=10126589\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Newberyite-38303.jpg","\u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FNewberyite\" class=\"extiw\" title=\"en:Newberyite\">Newberyite\u003C\u002Fa>\n\u003Cdl>\u003Cdd>\u003Cdl>\u003Cdd>Locality: Skipton Caves (Skipton lava caves; Mt Widderin Caves), Mt. Widderin (Anderson's Hill), \u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FSkipton\" class=\"extiw\" title=\"en:Skipton\">Skipton\u003C\u002Fa>, \u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FCorangamite_Shire\" class=\"extiw\" title=\"en:Corangamite Shire\">Corangamite Shire\u003C\u002Fa>, \u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FVictoria\" class=\"extiw\" title=\"en:Victoria\">Victoria\u003C\u002Fa>, Australia (\u003Ca rel=\"nofollow\" class=\"external text\" href=\"http:\u002F\u002Fwww.mindat.org\u002Floc-205.html\">Locality at mindat.org\u003C\u002Fa>)\u003C\u002Fdd>\n\u003Cdd>Newberyite is a rare magnesium phosphate, found first in a series of lava caves in Australia, the type locality (where this specimen is from). This specimen features an aggregate of rather large platy crystals. A fine specimen for this material! 3.2 x 2.5 x 1.9 cm\u003C\u002Fdd>\u003C\u002Fdl>\u003C\u002Fdd>\u003C\u002Fdl>","Robert M. Lavinsky",545,650,{"id":252,"source_url":253,"license_code":244,"credit_html":254,"title":255,"description":256,"author":248,"original_width":257,"original_height":258},17600,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=75500872","Robert M. Lavinsky, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=75500872\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Newberyite-400777.jpg","\u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FNewberyite\" class=\"extiw\" title=\"en:Newberyite\">Newberyite\u003C\u002Fa>\n\u003Cdl>\u003Cdd>\u003Cdl>\u003Cdd>Dimensions: 3 cm x 2.6 cm x 1.8 cm\u003C\u002Fdd>\n\u003Cdd>Locality: Skipton Caves (Skipton lava caves; Mt Widderin Caves), Mt. Widderin (Anderson's Hill), \u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FSkipton\" class=\"extiw\" title=\"en:Skipton\">Skipton\u003C\u002Fa>, \u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FCorangamite_Shire\" class=\"extiw\" title=\"en:Corangamite Shire\">Corangamite Shire\u003C\u002Fa>, \u003Ca href=\"https:\u002F\u002Fen.wikipedia.org\u002Fwiki\u002FVictoria\" class=\"extiw\" title=\"en:Victoria\">Victoria\u003C\u002Fa>, Australia (\u003Ca rel=\"nofollow\" class=\"external text\" href=\"http:\u002F\u002Fwww.mindat.org\u002Floc-205.html\">Locality at mindat.org\u003C\u002Fa>)\u003C\u002Fdd>\n\u003Cdd>Newberyite is a rare hydrated magnesium phosphate, found first in a series of lava caves deposited as bat guano in Australia, the Type Locality. This specimen features a sculptural aggregate of rather large platy crystals. A fine two-sided specimen for this rare material. Ex. Larry Krause specimen.\u003C\u002Fdd>\u003C\u002Fdl>\u003C\u002Fdd>\u003C\u002Fdl>",465,456,{"id":260,"source_url":261,"license_code":244,"credit_html":262,"title":263,"description":256,"author":248,"original_width":257,"original_height":264},17601,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=75500875","Robert M. Lavinsky, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=75500875\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Newberyite-400778.jpg",399,{"id":266,"source_url":267,"license_code":268,"credit_html":269,"title":270,"description":271,"author":272,"original_width":273,"original_height":274},17602,"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=118199173","CC BY-SA 2.0","Pacific Museum of Earth from Canada, via \u003Ca href=\"https:\u002F\u002Fcommons.wikimedia.org\u002F?curid=118199173\" rel=\"noopener\">Wikimedia Commons\u003C\u002Fa>","Newberyite (48522497381).jpg","\u003Cp>Mount Widdern\n\u003C\u002Fp>\nVictoria, Australia","Pacific Museum of Earth from Canada",6000,4000,[276,282,287],{"id":277,"url":278,"label":279,"formula":280,"spacegroup":281,"year":214},9893,"\u002Fcif\u002F9893.cif","Bartl 1983","P Mg O7 H7","P b c a",{"id":283,"url":284,"label":285,"formula":286,"spacegroup":281,"year":196},9894,"\u002Fcif\u002F9894.cif","Abbona 1979","Mg P O7 H7",{"id":288,"url":289,"label":290,"formula":286,"spacegroup":281,"year":186},9895,"\u002Fcif\u002F9895.cif","Sutor 1967",[292],"Newberyiet",[294,298,302,306,312,315,319],{"lang":295,"names":296},"ca",[297],"newberyita",{"lang":299,"names":300},"de",[301],"Newberyit",{"lang":303,"names":304},"eu",[305],"Newberyita",{"lang":307,"names":308},"fr",[309,310,311],"Hydrogénophosphate de magnésium trihydraté naturel","MgHPO4,3H2O (cristal)","Newbéryite",{"lang":313,"names":314},"it",[7],{"lang":316,"names":317},"uk",[318],"Ньюбериїт",{"lang":320,"names":321},"zh",[322],"镁磷石","Q3339100",{"history":11,"applications":11}]