Ferrorosemaryite, NaFe2+Fe3+Al(PO4)3, a new phosphate mineral from the Rubindi pegmatite, Rwanda

Hatert, Frédéric; Lefèvre, Pierre; Fransolet, André-Mathieu; Spirlet, M. R.; Rebbouh, Leila; Fontan, François; Keller, Paul A.

doi:10.1127/0935-1221/2005/0017-0749

Cited by 21 publications

(23 citation statements)

References 29 publications

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“…Fransolet (1995) interpreted the rosemaryite from the Buranga pegmatite, associated with secondary phosphates such as trolleite, as possibly originating by the oxidation of wyllieite. Likewise, Hatert et al (2005) described ferrorosemaryite, closely associated with trolleite, scorzalite and other low-temperature phosphatic phases. In addition, similar pegmatitic phosphates with Fe 3+ , such as bobfergusonite (Ercit et al 1986, Tait et al 2004) and even ferrisicklerite (Roda Robles et al 1998), are claimed to be primary and magmatic, whereas minerals considered typically primary are locally found to be metasomatic products (e.g., wolfeite; Masau et al 2000).…”

Section: The Origin Of Qingheiitementioning

confidence: 99%

The Association Qingheiite - Beusite - Lithiophilite in the Santa Ana Pegmatite, San Luis, Argentina

Galliski

Oyarzábal

Márquez-Zavalía

et al. 2009

The Canadian Mineralogist

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Qingheiite, the Mg end-member of the wyllieite group of transition-metal phosphates, with a formula Na 2 MnMgAl(PO 4 ) 3 and known so far only from the type locality, was discovered in a new occurrence and association. It was found in the Santa Ana mine (32°53'32" S, 65°55'43" W), San Luis province, Argentina, in a beryl type, beryl-columbite-phosphate subtype of rare-element pegmatite, and in the closely related La Empleada dike. At Santa Ana, qingheiite forms irregular granular veinlets or patches of deep jade-green color, ~0.5 cm thick, in a nodule of beusite interlaminated with lithiophilite. The average empirical formula is (Na 3.567  0. 421 SoMMAiReLa qingheïite, Na 2 MnMgAl(PO 4 ) 3 , le pôle magnésien du groupe de la wyllieïte dont les membres sont des phosphates de métaux de transition, et connue jusqu'à maintenant uniquement à sa localité type, a été trouvée dans une nouvelle association dans la pegmatite affleurant à la mine Santa Ana (32°53'32" S, 65°55'43" W), province de San Luis, en Argentine, ainsi que dans le filon semblable à La Empleada; il s'agit de pegmatites à éléments rares contenant béryl, columbite et phosphates. À Santa Ana, la qingheïite forme des veinules irrégulières de granules ou des taches de couleur vert-jade foncé, environ 0.5 cm en épaisseur, dans un nodule de béusite interlaminée avec la lithiophilite. La formule empirique moyenne est (Na 3.567  0.421 K 0.010 Ba 0.002 ) S4.000 (Na 2.000 ) S2.000 (Mn 1.806 Ca 0.167 Na 0.027 ) S2.000 roches hôtes suite à la cristallisation des zones de bordure et de paroi de la pegmatite. L'exsolution de ce précurseur a donné l'intercroissance lamellaire de béusite et de lithiophilite enrichie en Mg. La formation tardive de la qingheïite serait due à la présence de veines liées à la mise en place tardive d'un magma hyperalumineux riche en phase aqueuse.(Traduit par la Rédaction)

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Section: The Origin Of Qingheiitementioning

confidence: 99%

The Association Qingheiite - Beusite - Lithiophilite in the Santa Ana Pegmatite, San Luis, Argentina

Galliski

Oyarzábal

Márquez-Zavalía

et al. 2009

The Canadian Mineralogist

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“…7b), and Fe 2+ or Mn 2+ (or both) occupies the M(1) site. There are two end-member patterns of order: in rosemaryite and ferrorosemaryite (Hatert et al 2005(Hatert et al , 2006, M(2a) = Al and M(2b) = Fe 2+ (Fig. 7b, top), whereas in ferrowyllieite (Moore & Molin-Case 1974), M(2a) = Fe 2+ and M(2b) = Al (Fig.…”

Section: Cation Order In the Alluaudite-supergroup Mineralsmentioning

confidence: 99%

THE CRYSTAL STRUCTURE AND CRYSTAL CHEMISTRY OF MANITOBAITE, IDEALLY (Na16 )Mn2+ 25Al8(PO4)30, FROM CROSS LAKE, MANITOBA

Tait¹,

Ercit²,

Abdu³

et al. 2011

The Canadian Mineralogist

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The crystal structures of green (brown) variants of manitobaite, ideally (Na 16 )Mn 2+ 25 Al 8 (PO 4 ) 30 , monoclinic, Pc, Z = 2: green: a 13.4517(7), b 12.5266 (7), c 26.6765(13) Å, b 101.582(1)°, V 4403.6(7) Å 3 , D calc. 3.642 g/cm 3 ; brown: 13.4499(6), b 12.5046(5), c 26.6148(11) Å, b 101.221(1)°, V 4390.7(5)(3) Å 3 , D calc. 3.621 g/cm 3 , from pegmatite #22 at Cross Lake, Manitoba, Canada, have been solved by direct methods and refined to R 1 = 5.0 (6.0)% for 22,580 (25,613) unique (F o > 4sF) reflections collected on a Bruker single-crystal P4 diffractometer equipped with a 4K CCD detector and MoKa X-radiation. Chemical analysis by electron microprobe plus Fe 3+ determination by Mössbauer spectroscopy gave: green: P Zn 0.31 Al 6.58 Fe 3+ 2.09 P 30.15 O 120 . The general formula of manitobaite is (Na 16 )(Mn 2+ ,Fe 2+ ,Mg,Zn,Ca) 25 (Al,Fe 3+ ) 8 (PO 4 ) 30 , and the end-member formula is (Na 16 )Mn 2+ 25 Al 8 (PO 4 ) 30 . There are 80 cation sites and 120 anion sites in the structure. There are 30 tetrahedrally coordinated sites occupied by P, 33 octahedrally coordinated sites occupied by Mn 2+ , Fe 2+ , Al, Fe 3+ plus minor Mg and Zn, and 17 sites occupied predominantly by Na with coordination numbers from [5] to [8]. Manitobaite is an ordered superstructure of the alluaudite structure. In particular, there are eight octahedrally coordinated sites occupied predominantly by Al, emphasizing the key role of Al in producing superstructures in these minerals. SommAireNous avons résolu les structures cristallines de deux variantes de manitobaïte, l'une verte, l'autre brune, de formule idéale (Na 16 )Mn 2+ 25 Al 8 (PO 4 ) 30 , monoclinique, Pc, Z = 2: verte: a 13.4517 (7), b 12.5266 (7), c 26.6765(13) Å, b 101.582(1)°, V 4403.6(7) Å 3 , D calc. 3.642 g/cm 3 ; brune: 13.4499(6), b 12.5046(5), c 26.6148(11) Å, b 101.221(1)°, V 4390.7(5)(3) Å 3 , D calc. 3.621 g/cm 3 , les deux provenant de la pegmatite #22 au lac Cross, Manitoba, Canada, par méthodes directes, et nous les avons affiné jusqu'à un résidu R 1 de 5.0 (6.0)% pour 22,580 (25,613) réflexions uniques (F o > 4sF) prélevées avec un diffractomètre Bruker P4 pour monocristaux muni d'un détecteur 4K CCD et avec rayonnement MoKa. Des analyses chimiques avec une microsonde électronique en plus de déterminations du Fe 3+ par spectroscopie de Mössbauer ont donné: verte: P la formule du pôle est (Na 16 )Mn 2+ 25 Al 8 (PO 4 ) 30 . Il y a 80 sites cationiques et 120 sites anioniques dans la structure. Il y a 30 sites à coordinence tétraédrique à occupation par le P, 33 site à coordinence octaédrique à occupation par Mn 2+ , Fe 2+ , Al, Fe 3+ , avec Mg et Zn comme occupants mineurs, et 17 sites remplis surtout par Na en coordinence de [5] à [8]. La manitobaïte est une surstructure ordonnée de l'alluaudite. En particulier, il y a huit sites à coordinence octaédrique remplis surtout par Al, ce qui souligne le rôle primordial des cations Al dans la production de surstructures dans ces minéraux. (Traduit par la Rédaction)Mots-clés: manitobaïte, structure cristalli...

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“…Between 300 and 600°C, white powders without visible crystals were obtained, and the powder X-ray diffraction patterns correspond to those of alluaudite-type phosphates, without any supplementary reflection typical of the P2 1 /n wyllieite space group. As discussed by Hatert et al [2], however, the identification of actual wyllieite-type phosphates can only be confirmed by single-crystal X-ray diffraction techniques. At 700°C/3.5 kbar and 800°C/1 kbar, tiny acicular crystals were obtained and single-crystal structure refinements indicated an alluaudite-type structure [5].…”

mentioning

confidence: 98%

“…Nature of these globules is supposed to be fullerene-like. Due to appeared to the present time to high-resolution scanning probe microscopic methods difficulties with visualization nanometrical structural elements of metastable natural substances are removed [1,2]. We applied scanning tunneling (STM) and atomic force (AFM) microscopes.…”

mentioning

confidence: 99%

“…Consequently, the C2/c space group of alluaudite transforms into P2 1 /n in wyllieite, with no significant change of the unit-cell parameters, and with a structural formula which corresponds to X(2)X(1a)X(1b)M(1)M(2a) M(2b)(PO 4 ) 3 [1]. Recently, the description of the new mineral species ferrorosemaryite, NaFe 2+ Fe 3+ Al(PO 4 ) 3 , in the Rubindi pegmatite, Rwanda, initiated a detailed mineralogical study of the wyllieite group of minerals [2,3]. This study indicates that aluminium is localized on the M(2a) site of rosemaryite and ferrorosemaryite, not on the M(2b) site as observed in ferrowyllieite [1].…”

mentioning

confidence: 99%

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The transition from alluaudite- to wyllieite-type phosphates: which is the role really played by aluminium?

Hatert¹,

Fransolet²

2006

Acta Cryst Sect A

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Keywords: AFM-STM studies of minerals and glasses, supramolecular structures, Fourier TransformStudy of the noncrystalline solid carbon, which is responsible for the most essential properties of Precambrian shungite rocks (shungite occurrences in the north-western part of the lake Onega, Karelia, Russia), is of interest because of a number of its physic-chemical properties underlying its many perspective applications [1]. Shungite carbon has graphite-like structure at the atomic level, but high-temperature treatment of the carbon does not lead to its graphitization. Basic structural elements is globule. Shungite globule is a spherical or ellipsoidal multilayer carbon formation, about 10 nm in size. Nature of these globules is supposed to be fullerene-like. Due to appeared to the present time to high-resolution scanning probe microscopic methods difficulties with visualization nanometrical structural elements of metastable natural substances are removed [1,2]. We applied scanning tunneling (STM) and atomic force (AFM) microscopes. for study highly-carbonaceous (to 98%) shungite carbon from various deposits, which different pressure -temperature of formation are characterized [1]. The supermolecular globular structure is concerned with to genetic features of substances, first of all with pressure -temperature and features of material composition of mineral formation environments. As one of the basic regulation of the supermolecular constitution of the investigated substances logarithmically normal distributions of structural elements on the sizes can be distinguished. Such character of distribution can speak that visualized supermolecular elements are aggregates of colloidal particles. The following step in research of supermolecular constitution is the structural-morphological analysis of images to reveal elementary form of the ordering expressing in a periodic arrangement of structural elements. As a whole it reveals diffraction analysis the analogue of which is Fourieranalysis in our case. Fourier Transformation has confirmed visually observed absence of a regularity in a relative location of elements of supermolecular structures, however has allowed to reveal the presence morphological analysis of researched substances in a number of samples statistically noted directions it testifies to occurrence presence of original superstructures ordering. Possible mechanisms of aggregations of shungites globules were analyzed.[1] Buseck P.R., Galdobina L.P., Kovalevski V.V., Rozhkova N.N., The wyllieite group of minerals consists of Na-Mn-Fe-Albearing phosphates which exhibit a crystal structure topologically similar to the alluaudite structure. However, the ordering of cations in the wyllieite structure induces a splitting of the M(2) and X(1) sites of alluaudite into the M(2a) M(2b) and X(1a) X(1b) positions. Consequently, the C2/c space group of alluaudite transforms into P2 1 /n in wyllieite, with no significant change of the unit-cell parameters, and with a structural formula which corresponds to X(2)X(1a)X(1b)M (1)...

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Ferrorosemaryite, NaFe2+Fe3+Al(PO4)3, a new phosphate mineral from the Rubindi pegmatite, Rwanda

Cited by 21 publications

References 29 publications

The Association Qingheiite - Beusite - Lithiophilite in the Santa Ana Pegmatite, San Luis, Argentina

The Association Qingheiite - Beusite - Lithiophilite in the Santa Ana Pegmatite, San Luis, Argentina

THE CRYSTAL STRUCTURE AND CRYSTAL CHEMISTRY OF MANITOBAITE, IDEALLY (Na16 )Mn2+ 25Al8(PO4)30, FROM CROSS LAKE, MANITOBA

The transition from alluaudite- to wyllieite-type phosphates: which is the role really played by aluminium?

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