Manganese Sturmanite from the N’Chwaning 2 Mine, Kalahari, South Africa

The oxidation state of Mn is determined for the first time by iodine titrimetry, and the Mn 4+ /Mn 3+ ratio (54/46%) is identified for Mn-sturmanite from the N’Chwaning 2 Mine (Kalahari manganese field, South Africa). The Mössbauer spectrum of sturmanite, which contains a single asymmetric Lorentz d...

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Bibliographic Details
Published in:Geology of ore deposits 2023-12, Vol.65 (7), p.722-733
Main Authors: Gritsenko, Yu. D., Dedushenko, S. K., Vigasina, M. F., Pautov, L. A., Golubev, Ya. V., Ogorodova, L. P., Ksenofontov, D. A., Melchakova, L. V., Perfilyev, Yu. D.
Format: Article
Language:English
Subjects:
Analytical methods
Anhydrite
Anions
Borate minerals
Borates
Cations
Decomposition
Dehydration
Earth and Environmental Science
Earth Sciences
Haematite
Hematite
Infrared spectroscopy
Iodine
Iron
Manganese
Mineral Resources
Minerals
Mossbauer spectroscopy
Oxidation
Parameters
Polyhedra
Sulphates
Thermal analysis
Thermal transformations
Unit cell
Valence
X ray powder diffraction
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Summary:The oxidation state of Mn is determined for the first time by iodine titrimetry, and the Mn 4+ /Mn 3+ ratio (54/46%) is identified for Mn-sturmanite from the N’Chwaning 2 Mine (Kalahari manganese field, South Africa). The Mössbauer spectrum of sturmanite, which contains a single asymmetric Lorentz doublet with parameters RT IS α-Fe = 0.31(1) mm/s, RT QS = 0.18(1) mm/s, FWHM L = 0.55 mm/s, and FWHM R = 0.33 mm/s, confirms the presence of Fe 3+ only in the composition of the mineral. The process of its thermal transformation is studied using thermal analysis and IR spectroscopy: dehydration and decomposition of Ca polyhedra, dehydroxylation, decarbonatization, and complete decomposition of structure with the formation of anhydrite, hematite, and Ca borates occur up to 200, 600, 750, and 1000°C, respectively. The chemical formula of the studied sturmanite, which is calculated on the basis of our studies per eight cations, is as follows: Ca 5.94 Al 0.03 Si 0.02 [B(OH) 4 ] 1.00 [B(OH) 3 ] 0.11 [SO 4 ] 2.32 [СО 3 ] 0.49 (OH) 12 ⋅22.7H 2 O. The unit cell parameters of the mineral are determined using X-ray powder diffraction: a = 11.148(3) Å, c = 21.830(9) Å, and V = 2349(2) Å 3 . The unit cell parameters of minerals of the sturmanite–jouravskite series linearly decrease with an increasing mole amount of the jouravskite endmember. It is suggested that the studied mineral can be an intermediate member of the sturmanite–jouravskite series with heterovalent isomorphic substitution according to following schemes: Mn 3+ and Mn 4+ → Fe 3+ in the cation octahedral site and [CO 3 ] 2– → [B(OH) 4 ] – and [SO 4 ] 2– in the anion site.
ISSN:1075-7015
1555-6476
DOI:10.1134/S1075701523070036