Abstract
The nature of couple substitutions of minor and trace element chemistry of expitaxial intergrowths of wurtzite and sphalerite are reported. EPMA and laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) analyses display significant differences in the bulk chemistries of the two epitaxial intergrowth samples studied. The sample from the Animas-Chocaya Mine complex of Bolivia is Fe-rich with mean Fe levels of 4.8 wt% for wurztite-2H and 2.3 wt% for the sphalerite component, while the sample from Merelani Hills, Tanzania, is Mn-rich with mean Mn levels in wurztite-4H of 9.1 wt% and for the sphalerite component 7.9 wt% In both samples studied the wurtzite polytype is dominant over sphalerite. LA-ICP-MS line scans across the boundaries between the wurtzite and sphalerite domains within the two samples show significant variation in the trace element chemistries both between and within the two coexisting polytypes. In the Merelani Hills sample the Cu+ + Ga3+ = 2Zn2+ substitution holds across both the wurztite and sphalerite zones, but its levels range from around 1200 ppm of each of Cu and Ga to above 2000 ppm in the sphalerite region. The 2Ag+ + Sn4+ = 3Zn2+ coupled substitution does not occur in the material. In the Animas sample, the Cu+ + Ga3+ = 2Zn2+ substitution does not occur, but the 2(Ag,Cu)+ + Sn4+ = 3Zn2+ substitution holds across the sample despite the obvious growth zoning, although there is considerable variation in the Ag/Cu ratio, with Ag dominant over Cu at the base of the sample and Cu dominant at the top. The levels of 2(Ag,Cu)+ + Sn4+ = 3Zn2+ vary greatly across the sample from around 200 ppm to 8000 ppm Sn, but the higher values occur in the sphalerite bands.
Highlights
Sphalerite, the cubic close packed form of ZnS is the most abundant zinc mineral in the crust.In addition to being the principal ore of zinc, sphalerite is an important source of a number of other technologically important elements, including, Ga, Ge, In, and Cd
We examine the minor and trace element chemistry of such intergrowths from two well-known wurtzite occurrences where epitaxial intergrowths with sphalerite occur
The specimens analyzed in this study are from the collection of the South Australian Museum, Adelaide, Australia: (i) a banded epitaxial intergrowth of wurtzite-2H and sphalerite some 10 mm thick from the Animas-Chocaya Mine complex, Quechisla district, Bolivia (SAM G33739; denoted “Animas”) (Figure 1); and (ii) a crystal of wurtzite -4H with epitaxial zones of sphalerite from the Merelani Hills tanzanite deposit, 50 km SE of Arusha, Manyara Region, Tanzania (SAM G34171)
Summary
Sphalerite, the cubic close packed (ccp) form of ZnS is the most abundant zinc mineral in the crust. In addition to being the principal ore of zinc, sphalerite is an important source of a number of other technologically important elements, including, Ga, Ge, In, and Cd. ZnS occurs as a family of hexagonal closed packed (hcp) modifications (polytypes), known as wurtzite [1]. ZnS is apparently much rarer in nature than sphalerite, but may often be overlooked as ZnS is usually assumed to be sphalerite. The phase relations among the ZnS polytypes have been a matter of considerable debate for many years [3,4,5,6]. Allen and Minerals 2020, 10, 147; doi:10.3390/min10020147 www.mdpi.com/journal/minerals
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