On the miscibility gap of spinels MnxFe3−xO4+γ

Holba, Pavel; Khilla, M. A.; Krupička, S.

doi:10.1016/0022-3697(73)90030-9

Cited by 29 publications

(12 citation statements)

References 12 publications

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“…R reaches a minimum value of 0.89 in the magnetic hausmannite (12 wt.% Fe203). This is considerably lower than R = 0.93 (or 6.9 wt.% Fe203) envisaged by Mason (1943), Van Hook and Keitb (1958), Halba et al (1973), and Osawa et al (1992 as the room temperature stability limit for the solubility of iron in the hausmannite lattice in the system Mn304-MnFe204. The composition reported for the magnetic hausmannite falls, according to all these studies, into the two-phase region, the single phase 'magnetic hausmannite' should therefore be unstable.…”

Section: Discussionmentioning

confidence: 73%

Magnetic hausmannite from hydrothermally altered manganese ore in the Palaeoproterozoic Kalahari manganese deposit, Transvaal Supergroup, South Africa

Gutzmer¹,

Beukes²,

Kleyenstuber

et al. 1995

Mineral. mag.

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Hausmannite (Mn304), a manganese oxide with a tetragonally distorted spinel structure, is considered to be ferrimagnetic with a very low Curie temperature of 42.5 K. However, strongly magnetic hausmannite has been discovered in some of the hydrothermally altered high-grade manganese ores of the giant Kalahari manganese deposit in South Africa. EDS-electron microprobe analyses indicate magnetic hausmannite to contain on average between 3 and 11.3 wt.% Fe203. In contrast non-magnetic hausmannite contains on average about 1-3 wt.% Fe203. X-ray powder diffraction analyses reveal small changes in cell dimensions of the magnetic hausmannite related to the high iron content. M6ssbauer spectroscopy suggests that all iron is in the trivalent state. Optical microscopy and scanning electron microscopy (electron back-scatter imaging) proved the magnetic hausmannite to be homogeneous in composition, containing only a few minute inclusions of hematite. Magnetic blocking temperatures of the iron-rich hausmannite, approximating the Curie temperature, are of the order of 750 K. It is suggested that the ferrimagnetic state of hausmannite is stabilized and enhanced by replacement of Mn 3+ by Fe 3+.

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Section: Discussionmentioning

confidence: 73%

Magnetic hausmannite from hydrothermally altered manganese ore in the Palaeoproterozoic Kalahari manganese deposit, Transvaal Supergroup, South Africa

Gutzmer¹,

Beukes²,

Kleyenstuber

et al. 1995

Mineral. mag.

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“…In 1970s the study of equilibria of oxides with atmosphere was also stimulated by the industry´s interest in the production of new ceramic materials (e.g., ferrites [1,26]) of required properties using an adequate high-temperature preparation procedure. Consequently, a new thermodynamic school developed in cooperation between the Czech Institute of Physics and the University of Chemistry and Technology (former Institutre of Chemical Technology) hindered at that time by political repressions [53] revealed in 1990´s [14][15][16] and successively continued through the studies of oxide high-temperature superconductors [3][4][5][6][7] and followed by others (e.g.…”

Section: Historical Rootsmentioning

confidence: 99%

“…most recently cobaltites [9][10][11] prominent for their thermoelectric properties). However, in spite of so much work, which was concentrated on these systems of variable solid-gas interaction [1][2][3][4][5][6][7][8][9][10][11] no adequate thermodynamic resolution towards the partly open systems became accessible so that the case of related hyperfree energy is worth of more detailed presentation.…”

Section: Historical Rootsmentioning

confidence: 99%

“…The recently emerging subject of oxides with variable stoichiometry including their phase equilibria with environment affected the novel field of thermodynamics of nonstoichiometric solids. This field has been promoted by Czech studies, the typical cases of which are represented by either spinels [1,2], superconductors [3][4][5][6], magnetoresistance manganites [7,8] or thermoelectric cobaltites [9][10][11] which required a novel approach for treating the interaction between a ceramic material and atmospheric oxygen. It is worth noting that the core of the associated innovative thermodynamic approach was laid by Czech chemist Pavel Holba [12][13][14][15][16] as a continuation of the respected Czech thermodynamic school commenced by Šatava [17,18] whose international impact is worth of a more detailed analysis.…”

Section: Introductionmentioning

confidence: 99%

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On the History and Recent Applications of Hyperfree Energy Describing Thermodynamics of Mobile Components in Partly Open Ceramic Systems

Sedmidubský¹

2017

Ceramics - Silikaty

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Nonstoichiometric oxides form a new chapter in tailored materials. Founding and construction of thermodynamic functions related to solid (geologic) materials is traced showing interactions between Czech Professor F. Wald and Russians R.S. Kurnakov and D.S. Korzhinskiy in the early definition of phases and characterization of partly open systems. Development of thermodynamic concepts regarding solid-state description is reviewed. For the associated definition of a mobile component the hyperfree energy was invented and recently applied on several systems. A novel term plutability is put forward as a measure of material susceptibility towards free component uptake as a result of varying predictors such as temperature, pressure and activity. Ehrenfest-like equations involving the changes of plutabilities were derived.

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“…The phase diagram of the Fe/Mn/O system [5] shows that the spinel phase can be obtained in air at temperature above 950'C. Only a few works have been published on the synthesis of this stoechiometric spinel at low temperature [3,6,7]. Probably, the difficulty to obtain the stoechiometric spinel at low temperature is due to, the need of a better control of the reduction atmosphere, the weak crystallinity of the samples and the immiscibility gap described by Masson [8] for the natural "wredenburgite".…”

Section: Introductionmentioning

confidence: 99%

Iron Manganites Synthesis by the Soft Chemistry Method

et al. 2001

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The iron manganites FexMn( 3 _X)0 4 synthesis by soft chemistry method have been studied. The main difficulty is to obtain single phase spinel with high Mn content (0.4< x < 1.3). Oxalate precursor powders of these materials with controlled shape and nanoscopic size have been prepared. The precursors are then heat treated with a H2/H 2 O/N 2 gas mixture at low temperature. The resulting stoechiometric spinels are metastable phases with high specific surface area and are highly reactive toward oxygen. Therefore, these oxide can be oxidized in air at low temperature in order to produce mixed valence defect manganites 0 4+8 with a good reproducibility on the oxygen content. Although, some problems persist for the higher Mn contents, as the oxygen partial pressure for the reduction must be controlled precisely in order to produce the stoechiometric spinel at low temperature. The development of a low temperature reduction system, with oxygen partial pressure controlled by oxygen electrochemical pumping, is in progress.

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On the miscibility gap of spinels MnxFe3−xO4+γ

Cited by 29 publications

References 12 publications

Magnetic hausmannite from hydrothermally altered manganese ore in the Palaeoproterozoic Kalahari manganese deposit, Transvaal Supergroup, South Africa

Magnetic hausmannite from hydrothermally altered manganese ore in the Palaeoproterozoic Kalahari manganese deposit, Transvaal Supergroup, South Africa

On the History and Recent Applications of Hyperfree Energy Describing Thermodynamics of Mobile Components in Partly Open Ceramic Systems

Iron Manganites Synthesis by the Soft Chemistry Method

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