• journal_title：Mineralogical Magazine
• Contributor：E. S. Grew ; A. T. Rao ; K. K. V. S. Raju ; C. Hejny ; J. M. Moore ; D. J. Waters ; M. G. Yates ; C. K. Shearer
• Publisher：Mineralogical Society of Great Britain and Ireland
• Date：2003-
• Format：text/html
• Language：en
• Identifier：10.1180/0026461036750144
• journal_abbrev：Mineralogical Magazine
• issn：0026-461X
• volume：67
• issue：5
• firstpage：1081
• section：Articles

d="p-1">Fluorine-rich prismatine, (□,Fe,Mg)(Mg,Al,Fe)₅Al₄(Si,B,Al)₅O₂₁(OH,F), with F/(OH+F) = 0.36–0.40 and hercynite are major constituents of a Fe-Al-B-rich lens in ultrahigh-temperature granulite-facies quartz-sillimanite-hypersthene-cordierite gneisses of the Eastern Ghats belt, Andhra Pradesh, India. Hemoilmenite, sapphirine, magnetite, biotite and sillimanite are subordinate. Lithium, Be and B are concentrated in prismatine (140 ppm Li, 170 ppm Be, and 2.8–3.0 wt.% B₂O₃). Another Fe-rich lens is dominantly magnetite, which encloses fine-grained zincian ferrohögbomite-2N2S, (Fe²⁺,Mg,Zn,Al)₆ (Al,Fe³⁺,Ti)₁₆O₃₀(OH)₂, containing minor Ga₂O₃ (0.30–0.92 wt.%). Fe-Al-B-rich lenses with prismatine (or kornerupine) constitute a distinctive type of B-enrichment in granulite-facies rocks and have been reported from four other localities worldwide. A scenario involving a tourmaline-enriched lateritic precursor affected by dehydration melting is our preferred explanation for the origin of the Fe-Al-B-rich lenses at the five localities. Whole-rock analyses and field relationships at another of these localities, Bok se Puts, Namaqualand, South Africa, are consistent with this scenario. Under granulite-facies conditions, tourmaline would have broken down to give kornerupine-prismatine (±other borosilicates) plus a sodic melt containing H₂O and B. Removal of this melt depleted the rock in Na and B, but the formation of ferromagnesian borosilicate phases in the restite prevented total loss of B.