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Gatehouseite, a new manganese hydroxy phosphate from Iron Monarch, South Australia

Published online by Cambridge University Press:  05 July 2018

A. Pring  and
W. D. Birch
A. Pring
Affiliation:
Department of Mineralogy, South Australian Museum, North Terrace, Adelaide, South Australia 5000, Australia
W. D. Birch
Affiliation:
Department of Mineralogy, Museum of Victoria, 285 Russell Street, Melbourne, Victoria 3000, Australia
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Abstract

Gatehouseite is a new manganese hydroxy phosphate from Iron Monarch, South Australia. The new mineral occurs as radiating clusters of pale yellow, and yellow to pale brownish orange bladed crystals up to 100 ~tm in length. The crystals are elongated along [010] and the principal forms are {102}, {110} and {001}. Gatehouseite also occurs as overgrowths on prismatic arsenoclasite crystals. Associated with gatehouseite are baryte, shigaite, manganoan ferroan calcite, hausmannite and hematite. Gatehouseite appears to have formed at low temperature by the interaction of phosphorus-rich fluids on hausmannite in carbonate-rich fractures in the hematite ore. Electron microprobe analysis yielded: MnO 64.42, FeO 0.19, CuO 0.03, ZnO 0.03, PbO 0.05, Al2O3 0.10, P2O5 22.18, V2O5 0.38, As2O5 3.58, H2O (6.44%). These data gave an empirical formula of Mn5.09Fe0.01Al0.01(P1.75As0.17-V0.02)∑1.94O8(OH)4.00, calculated on the basis of 12 oxygen atoms. The simplified formula is Mn5(PO4)2(OH)4. The mineral is transparent with a pale yellow streak, an adamantine lustre and an estimated Mohs hardness of 4. The crystals exhibit a distinct cleavage on {010} and have a splintery fracture. The strongest lines in the X-ray powder pattern are (dobs, Iobs, hkl) 4.48 (10) (004); 4.03 (10) (104); 2.900 (100) (11.5); 2.853 (70) (106); 2.801 (50) (021); 2.702 (80) (303); 2.022 (15) (322); 1.608(15) (330). These data were indexed on an orthorhombic cell, with a = 9.097(2), b = 5.693(2), c = 18.002(10) Å and a volume of 932.4(8) Å3; the space group is probably P212121. For Z = 4 and using the empirical formula, the calculated density is 3.74 g/cm3. Optical properties could not be determined in full; two refractive indices are 1.74(1) and 1.76(1) (white light); pleochroism is distinct from brown to near colourless. The crystals are length slow with parallel extinction. The name is for Dr. Bryan Michael Kenneth Cummings Gatehouse (1932-), crystal chemist of Monash University, Melbourne, Australia.

Keywords

gatehouseitenew mineralmanganese hydroxy phosphatearsenoclasiteIron MonarchSouth Australia
Type
Mineralogy
Information
Mineralogical Magazine , Volume 57 , Issue 387 , June 1993 , pp. 309 - 313
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1993

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References

Aminoff, G. (1931) Arsenoklasite, a new arsenate from Långban. Kungl. Svenska Vetenlskapskad. Handl., 9, 527.Google Scholar
Berry, L. G. (1951) Observations on conichalchite, cornwallite, euchroite, liroconite and olivenite. Am. Mineral., 36, 484503.Google Scholar
Miles, K. R. (1954) The geology and iron ore resources of the Middleback Range Area. Geological Survey of South Australia, Bull., 33, 245 pp.Google Scholar
Moore, P. B. (1967) Contributions to Swedish mineralogy I. Studies on the basic arsenates of manganese: retzian, hemafibrite, synadelphite, arsenoclasite, arseniopleite, and akrochordite. Ark. f. Mineral. Geol., 4, 425–43.Google Scholar
Moore, P. B. and Molin-Case, J. (1971) Crystal chemistry of the basic manganese arsenates: V. Mixed manganeses coordination in the atomic arrangement of arsenoclasite. Am. Mineral.,. 56, 1539–52.Google Scholar
Pring, A., Francis, G. L., and Birch, W. D. (1989) Pyrobelonite, arsenoklasite, switzerite and other recent finds at Iron Monarch, South Australia. Austral. Mineral., 4, 4955.Google Scholar
Pring, A., Francis, G. L., and Birch, W. D. (1992a) Nissonite, namibite, and other additions to the mineral suite from Iron Monarch, South Australia. Ibid., 6, 31-9.Google Scholar
Pring, A., Slade, P. G., and Birch, W. D. (1992b) Shigaite from Iron Monarch, South Australia. Mineral. Mag., 56, 417–8.Google Scholar
Ruszala, F. A., Anderson, J. B., and Kostiner, E. (1977) Crystal structures of two isomorphs of arsenoclasite: Cos(PO4)2(OH)4 and Mns(PO4)2(OH)4. Inorg. Chem., 16, 2417–22.Google Scholar
Schoemaker, G. L. and Kostiner, E. (1981) Polymor-phism inCns(PO4)2(OH)4. Am. Mineral., 66, 178–81.Google Scholar