Nickel-rich chromian muscovite from the Indus suture ophiolite, NW Pakistan: Implications for emerald genesis and exploration

Ubiquitous veins and stockworks of quartz traverse the ophiolitic emerald-hosting, carbonate-altered ultramafic rocks in the Swat Valley. Some of the emerald-bearing quartz veins contain chromian muscovite and tourmaline. In addition, veins and clusters consisting of chromian muscovite and/or tourmaline occur in zones of carbonate-altered rocks where the quartz veins are most abundant. The chromian muscovite is characterized by high Mg/Fe ratios (4‐9) and contains variable and in some cases anomalously high concentration of Ni (ranging up to 9 wt% NiO). A detailed investigation reveals that the Ni and Mg entered the chromian muscovite structure as a part of a complex coupled substitution: (Fe VI , Mn VI , Mg VI , Ni VI ) 2+ + [Si IV ] 4+ ↔ (Al VI , Cr VI ) 3+ + [Al IV ] 3+ . The stable coexistence of quartz, chromian muscovite, tourmaline and emerald suggests that all these phases are cogenetic and precipitated from Si-rich, Al-, Be-, B- and K-bearing fluids related to a single episode of hydrothermal activity. The Mg, Cr and Ni contents in chromian muscovite were most probably extracted by the percolating hydrothermal solutions from the host carbonate-altered ultramafic rocks through wall rock reaction. The observed high variability in the Mg, Cr and Ni contents of chromian muscovite probably reflects low mobility of these elements during the hydrothermal process or a result of local equilibrium under relatively low T conditions.

[1]  R. Barnett,et al.  Corundum, Cr-muscovite rocks at O'Briens, Zimbabwe: the conjunction of hydrothermal desilicification and LIL-element enrichment — geochemical and isotopic evidence , 1987 .

[2]  P. Treloar Chromian muscovites and epidotes from Outokumpu, Finland , 1987, Mineralogical Magazine.

[3]  J. Hammarstrom Mineral Chemistry of Emeralds and Some Associated Minerals from Pakistan and Afghanistan: an Electron Microprobe Study , 1989 .

[4]  W. Schreyer A discussion of: “Corundum, Cr-muscovite rocks at O'Briens, Zimbabwe: the conjunction of hydrothermal desilicification and LIL-element enrichment — geochemical and isotopic evidence” by Kerrich et al. , 1988 .

[5]  R. Howie,et al.  An Introduction to the Rock-Forming Minerals , 1966 .

[6]  L. Snee,et al.  Mingora emerald deposits (Pakistan); suture-associated gem mineralization , 1986 .

[7]  W. Schreyer,et al.  Corundum-Fuchsite Rocks in Greenstone Belts of Southern Africa: Petrology, Geochemistry, and Possible Origin , 1981 .

[8]  M. Fleet,et al.  Barian feldspar and barian-chromian muscovite from the Hemlo area, Ontario , 1991 .

[9]  P. Treloar The Cr-minerals of Outokumpu—Their Chemistry and Significance , 1987 .

[10]  G. A. Challis,et al.  Chromian muscovite, uvarovite, and zincian chromite; products of regional metasomatism in Northwest Nelson, New Zealand , 1995 .

[11]  D. Ackermand,et al.  Mineralogy of chromiferous quartzites from South India , 1983 .

[12]  B. Windley,et al.  K‐Ar and Ar‐Ar geochronology of the Himalayan collision in NW Pakistan: Constraints on the timing of suturing, deformation, metamorphism and uplift , 1989 .

[13]  M. Arif,et al.  Chemistry of chromite and associated phases from the Shangla ultramafic body in the Indus suture zone of Pakistan , 1993, Geological Society, London, Special Publications.

[14]  A. Fallick,et al.  The genesis of emeralds and their host rocks from Swat, northwestern Pakistan: a stable-isotope investigation , 1996 .

[15]  R. Barnett,et al.  Reply to: “A discussion of corundum, Cr-muscovite rocks at O'Briens, Zimbabwe: the conjunction of hydrothermal desilicification and LIL-element enrichment-geochemical and isotopic evidence/rd , 1988 .

[16]  L. Snee,et al.  Geological Setting of the Emerald Deposits , 1989 .