Ferronigerite-2N1S
Ferronigerite-2N1S is an iron, tin, alumino-hydroxide mineral that naturally occurs around sillimanite-quartz veins. Ferronigerite-2N1S belongs to the nigerite group, högbomite supergroup. The other constituents of the nigerite group are ferronigerite-6N6S, magnesionigerite-2N1S, magnesionigerite-6N6S, zinconigerite-2N1S and zinconigerite-6N6S.[5] The 2N1S ending stands for the nolanite and spinel structural layers.[4]
Ferronigerite-2N1S | |
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General | |
Category | Oxide minerals |
Formula (repeating unit) | (Zn,Mg,Fe2+)(Sn,Zn)2(Al,Fe3+)12O22(OH)2 |
IMA symbol | Fng-2N1S[1] |
Strunz classification | 4.FC.20 |
Crystal system | Trigonal |
Crystal class | Hexagonal scalenohedral (3m) H-M symbol: (3 2/m) |
Space group | P3m1 |
Identification | |
References | [2][3][4] |
Ferronigerite-2N1S was first discovered in the Kabba province of central Nigeria in 1944; it was originally named Nigerite. Its name was later changed to nigerite-6H then to nigerite-6T and in 2003 ferronigertie-2N1S was approved by the International Mineralogical Association.
Chemical composition
The general chemical formula of ferronigertie-2N1S is (Zn,Mg,Fe2+)(Sn,Zn)2(Al,Fe3+)12O22(OH)2[4] or Sn(Fe,Mg)Al6O11(OH).[3]
Its percent composition is 50.91% Al2O3, 25.33% SnO2, 11.90% Fe2O3, 4.51% ZnO, 2.65% FeO, 1.57% H2O, 1.28% MgO, and less than 1% of PbO, SiO2, TiO2 and MnO. Due to its chemical composition, it is not susceptible to decomposition or solubility in acids. Ferronigerite-2N1S has also been found in some cases to have a lithium substitution for tin and titanium; this aids in charge balancing.
Properties
Ferronigerite-2N1S possesses no prominent cleavage but does possess a weak basal cleavage. It has a light grey to white streak, and often is shiny dark brown in color. Although the color can also be yellow to light brown. The variance of color is due to the individual composition to the mineral and where it is found geologically. It has a relative hardness of 8-9 on Mohs relative hardness scale.
Structure
Ferronigerite-2N1S crystallizes in the trigonal 32/m crystal class and a space group of P3m1. It exhibits two types of close pack structures: cubic close packed and hexagonal close packed. This results in ferronigerite-2N1S looking like simple hexagonal plates.
Geologic occurrence
Ferronigerite-2N1S has been found to be associated with Precambrian schists, gneisses, and granites, in the Tsomtsaub tin mine in the Egbe District, Kabba Provence in central Nigeria. It is generally associated with microcline-quartz-pegmatites in small amounts and limited in association only to that of old granite, shists, and gneisses. It is also associated with microcline-quartz-mica-pegmities, which make up to bulk of economically advantageous deposits of cassiterite where Ferronigerite-2N1S is found in association. The most common geologic structure where it is present is in sillimanite-quartz veins which are paired closely with gahnite. While microcline-quartz-mica-pegmities and Precambrian schists, gneisses and granites are common in Africa, sillimanite-quartz veins are more common in other parts of the world.
References
- Warr, L.N. (2021). "IMA–CNMNC approved mineral symbols". Mineralogical Magazine. 85 (3): 291–320. Bibcode:2021MinM...85..291W. doi:10.1180/mgm.2021.43. S2CID 235729616.
- Mineralienatlas
- Ferronigerite-2N1S on Mindat.org
- Ferronigerite-2N1S data on Webmineral
- Nigerite group on Mindat.org
Further reading
- Arakcheeva, A.V., Pushcarovski, D.Y., Rastsvetaeva, R.K.,Kashaev, A.A., & Nadexhina, T.N. (1995). Crystal structure of nigerite-5H. Crystallography Reports, 40, 587-592.
- Armbruster, T. (2002) Revised nomenclature of Hogbomite, nigerite, and taaffeite minerals. European Journal of Mineralogy, 14(2), 389-395.
- Armbruster, T., & Feenstra, A. (2004). Lithium in nigerite-group minerals. European journal of mineralogy, 16(2), 247-254. Chicago
- Bannister, F.A., Hey, M.H., Stadler, H.P. (1947) Nigerite, a new tin mineral. Mineral. Mag., 28, 128–136.
- Grey, I.E. & Gatehouse, B.M. (1979) The crystal structure of nigerite-24R. Am. Mineral., 64, 1255–1264.
- Grice and Farraris (2003). New minerals approved in 2002 and nomenclature modifications approved 1998–2002 by the Commission on New Minerals and Mineral Names, International Mineralogical Association. American Mineralogist, 88, 1620-1624.
- Jacobson, R., & Webb, J. S. (1947). The occurrence of nigerite, a new tin mineral in quartz- sillimanite-rocks from Nigeria. Mineral. Mag, 28, 118-128.
- Kloosterman, J. B. (1974). Nigerite in the tin-tantalum pegmatites of Amapa, Brazil. Mineral Mag, 39, 837-846. Chicago
- McKie, D. (1963) The högbomite polytypes. Mineral. Mag, 33, 563–580.
- Nickel, E.H. (1993) Standardization of polytype suffixes. Can. Mineral., 31, 767–768.
- Novák, M., Vieira, R., Lima, A., Skoda, R., Martins, T., & dos Anjos Ribeiro, M. (2009). Ferronigerite with dominant substitution TiSn1 in muscovite+ chlorite aggregate from massive quartz nodule associated with a petalite-rich aplite-pegmatite of the Barroso-Alvao pegmatite field, Northern Portugal. Neues Jahrbuch für Mineralogie- Abhandlungen, 186(1), 67-78.
- Peacor, D.R. (1967) New data on nigerite. Am. Mineral., 52, 864–866.
- Rouse, R. C., & Peacor, D. R. (1968). The relationship between senaite, magnetoplumbite and davidite. Am. Mineral, 53, 869-879.
- Schumacher, J. C., Schäfer, K., & Seifert, F. (1987). Lamellar nigerite in Zn-rich spinel from the Falun deposit, Sweden. Contributions to Mineralogy and Petrology 95 (2), 182-190.
- Van Tassel, R. (1965). Nigerite from Lixa, near Felgueiras, Douro Litoral province, Portugal. Mineral Mag, 34, 482-486.