Donnayite-(Y)

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Donnayite-(Y)
Donnayite-(Y)-169861.jpg
Donnayite-(Y) (field of view: c. 2 cm)
General
Category Carbonate minerals
Formula
(repeating unit)		NaCaSr3Y(CO3)6∙3H2O
IMA symbol Dna-Y [1]
Strunz classification 5.CC.05
Crystal system Triclinic
Crystal class Pedial (1)
(same H-M symbol)
Space group P1
Identification
Mohs scale hardness3
References [2] [3] [4] [5]

Donnayite-(Y) is a rare-earth carbonate mineral containing the rare-earth metal yttrium. It was first discovered in 1978 at Mont Saint-Hilaire, Quebec. Donnayite was subsequently identified and named after Joseph D. H. Donnay and his wife, Gabrielle Donnay. Both were prominent mineralogists and crystallographers, and J. D. H. Donnay was awarded the Roebling Award by the Mineralogical Society of America in 1971 for his emphasis on the importance of optical mineralogy and crystal morphology. Donnayite tends to occur in small quantities in the pegmatite dykes and miarolitic cavities of mountainous regions. It crystallizes in this environment with increasing alkalinity values until the alkalinity suddenly drops during the last stage of crystallization. This results in increasing amounts of Na carbonates and REE minerals. First discovered at Mont St-Hilaire, donnayite has since been found in the Southern Ural Mountains of Russia and the Narssarssuk pegmatite of South Greenland. Donnayite crystals tend to be small and the color is commonly pale yellow to yellow with a white streak and a vitreous luster. Donnayite crystals usually display trigonal or hexagonal symmetry and have a hardness of 3. Twinning is extremely common in this mineral. Minerals closely related to donnayite include synchysite, calcite, sphalerite, microcline, and analcime. Donnayite is isomorphous with weloganite and mckelveyite.

Contents

Composition

The chemical formula of donnayite is: NaCaSr3Y(CO3)6·3H2O. Donnayite is composed of the cations sodium, calcium, strontium, and yttrium. Of these cations, strontium and yttrium are the most prominent. In addition to this, donnayite contains a significant amount of water, making it a hydrated mineral (more specifically, a hydrated carbonate). Generally speaking, mineral hydration occurs when water is added to the structure of the mineral, which occurs in retrograde metamorphism (when temperatures during crystallization suddenly drop, and H activity increases). Donnayite was first analyzed using a Cambridge MK5 electron microprobe. Electron microprobe analysis of donnayite in 1978 yielded the following weight percent oxides (Baker et al., 1978):

OxideWeight %
Na2O3.37
CaO5.75
BaO0.85
SrO35.8
Y2O313.1
Nd2O31.83
La2O30.45
CO230.98
H2O6.34
Total98.47

The CO2 and H2O values given were calculated on the basis of 6(CO3)-2 and 3(H2O) per formula by comparison with weloganite.

Structure

Donnayite consists of six carbonate anions, together with three H2O molecules. The asymmetric unit contains three independent sites occupied by Sr and three additional sites occupied by Na+, Ca2+, or Y3+. Each strontium atom is bonded to 10 oxygen atoms. Donnayite has a structure very similar to shomiokite-(Y). The Na(CO3)·H2O of shomiokite are cross-linked through the layers of Y polyhedra, which results in "mixed" carbonate layers. In this "mixed" layer, the CO3 triangles are tilted within the layer, which allows the H2O groups and Na octahedral to share the slab with the CO2 polyhedra. The (Na, Y)CO3·H2O layer of donnayite is comparable to this. However, the Sr atoms of donnayite have 9-fold coordination with an extra layer of flat-lying carbonate groups. This is shown in the figure below. In the structure of the REE carbonate, donnayite, the effects of H-bonding are negligible.

Physical properties

Typical donnayite crystals are very small, ranging from 0.05 to 1.0 mm and rarely reaching 2.0 mm. Donnayite is commonly pale yellow to yellow, but can also be colorless, white, gray, and very rarely, reddish brown, due to hematite inclusions. The streak of this mineral is white, and it has a vitreous luster. Donnayite ranks at a hardness of 3 on Mohs scale and has fair to imperfect cleavage on the c axis {001}. Donnayite crystals usually display trigonal or hexagonal symmetry and belong to the point group 1 or 3m and the space group P1. Optically, donnayite is biaxial negative with a 2v (measured) ranging from 0° to 30°.

ColorYellow
StreakWhite
LusterVitreous
Hardness3
Cleavage{001}
SymmetryTrigonal/hexagonal
Point Group1 or 3m

Geologic occurrence

Donnayite occurs in minute quantities in the pegmatite dykes, miarolitic cavities, and interstices in the nepheline syenites at Mont St-Hilaire, Quebec. It is usually found in rocks from the alkaline complexes and in carbonatites. During crystallization of the nepheline syenite, the alkalinity continues to increase until the very last stage, when the alkalinity suddenly drops, resulting in decreasing temperature and an increase in H activity. This is exemplified by increasing amounts of Na carbonates and REE minerals. In addition, during the last stages of crystallization in more acidic conditions, minerals form with increasing amounts of H2O, and REE minerals rich in Y. In 1973, donnayite was first discovered at Mont St-Hilaire, but was incorrectly identified as "brockite". Finally, in 1978 it became possible to gather sufficient data to characterize this sample as the new species, donnayite. In addition to this geologic occurrence, donnayite can be found in Russia at Mt. Kukisvumchorr, Khibiny massif, Kola Peninsula, and at the Vishnevogorsk complex, Vishnevy-Ilmen Mountains, Southern Ural Mountains. Recently, donnayite has been discovered along with ewaldite, epitaxially intergrown, in crystals from the Narsaarsuk pegmatite in South Greenland. Related minerals include ewaldite, mckelveyite, synchysite, calcite, sphalerite, microcline, and analcime.

Special characteristics

As of today, donnayite has no real historical or political significance. There are no common uses for this mineral, and it is not used for the fabrication of any known products. The characteristics that make donnayite special are its small size, and the few locations on Earth at which this mineral can be found. It requires a unique environment to form and crystallize, and for this reason donnayite has only been found in three countries of the world. Another characteristic that makes donnayite unique is the fact that it contains the REE, yttrium, as an essential constituent. Although donnayite has no known human uses, it has other characteristics that make it distinct and for this reason most people do not even know this mineral exists.

Name

Donnayite was named in honor of Joseph Desire Hubert Donnay, and his wife, Gabrielle Donnay (Baker et al., 1978). J. D. H. Donnay (1902–1994) was an accomplished Belgian-American-Canadian crystallographer and mineralogist, and professor at Johns Hopkins University. He served as president of the Mineralogical Society of America and in 1971 was awarded its highest honor, the Roebling Medal. Donnay emphasized the importance of optical mineralogy and crystal morphology and how they related to crystal structure. He is the author of 100 abstracts, 148 papers, 36 books (or chapters in books), 38 reviews, and several non-scientific papers. His wife, Dr. Gabrielle Donnay, was a professor of crystallography at McGill University in Montreal, Canada where Dr. J. D. H. Donnay later became Research Associate and a guest professor.

Related Research Articles

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<span class="mw-page-title-main">Strontianite</span> Rare carbonate mineral and raw material for the extraction of strontium

Strontianite (SrCO3) is an important raw material for the extraction of strontium. It is a rare carbonate mineral and one of only a few strontium minerals. It is a member of the aragonite group.

<span class="mw-page-title-main">Natron</span> Carbonate mineral

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<span class="mw-page-title-main">Weloganite</span>

Weloganite is a rare carbonate mineral with formula: Na2(Sr,Ca)3Zr(CO3)6·3H2O. It was discovered by Canadian government mineralogist Ann P. Sabina in 1967 and named for Canadian geologist Sir William Edmond Logan (1798–1875). It was first discovered in Francon Quarry, Montreal, Quebec, Canada and has only been reported from a few localities worldwide.

<span class="mw-page-title-main">Eudialyte</span> Cyclosilicate mineral

Eudialyte, whose name derives from the Greek phrase Εὖ διάλυτος, eu dialytos, meaning "well decomposable", is a somewhat rare, nine member ring cyclosilicate mineral, which forms in alkaline igneous rocks, such as nepheline syenites. Its name alludes to its ready solubility in acid.

<span class="mw-page-title-main">Lanthanite</span>

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<span class="mw-page-title-main">Abenakiite-(Ce)</span> Cyclosilicate mineral

Abenakiite-(Ce) is a mineral of sodium, cerium, neodymium, lanthanum, praseodymium, thorium, samarium, oxygen, sulfur, carbon, phosphorus, and silicon with a chemical formula Na26Ce6(SiO3)6(PO4)6(CO3)6(S4+O2)O. The silicate groups may be given as the cyclic Si6O18 grouping. The mineral is named after the Abenaki, an Algonquian Indian tribe of New England. Its Mohs scale rating is 4 to 5.

<span class="mw-page-title-main">Mckelveyite-(Y)</span>

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<span class="mw-page-title-main">Normandite</span>

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<span class="mw-page-title-main">Quintinite</span>

Quintinite is a carbonate mineral with the chemical formula Mg4Al2(OH)12CO3⋅3H2O.

<span class="mw-page-title-main">Serandite</span> Mineral

Serandite is a mineral with formula Na(Mn2+,Ca)2Si3O8(OH). The mineral was discovered in Guinea in 1931 and named for J. M. Sérand. Serandite is generally red, brown, black or colorless. The correct name lacks an accent.

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<span class="mw-page-title-main">Zirsilite-(Ce)</span>

Zirsilite-(Ce) is a very rare mineral of the eudialyte group, with formula (Na,□)12(Ce,Na)3Ca6Mn3Zr3NbSi(Si9O27)2(Si3O9)2O(OH)3(CO3)·H2O. The original formula was extended to show the presence of cyclic silicate groups and the presence of silicon at the M4 site, according to the nomenclature of the eudialyte group.according to the nomenclature of eudialyte group. Zirsilite-(Ce) differs from carbokentbrooksite in cerium-dominance over sodium only. Both minerals are intimately associated. The only other currently known representative of the eudialyte group having rare earth elements (in particular cerium, as suggested by the "-Ce)" Levinson suffix in the name) in dominance is johnsenite-(Ce).

<span class="mw-page-title-main">Ferrokentbrooksite</span> Mineral of the eudialyte group

Ferrokentbrooksite is a moderately rare mineral of the eudialyte group, with formula Na15Ca6(Fe,Mn)3Zr3NbSi25O73(O,OH,H2O)3(Cl,F,OH)2. The original formula was extended form to show the presence of cyclic silicate groups and presence of silicon at the M4 site, according to the nomenclature of eudialyte group. As suggested by its name, it is the (ferrous) iron analogue of kentbrooksite. When compared to the latter, it is also chlorine-dominant instead of being fluorine-dominant. The original (holotype) material is also relatively enriched in rare earth elements, including cerium and yttrium.

Johnsenite-(Ce) is a very rare mineral of the eudialyte group, with the chemical formula Na12(Ce,La,Sr,Ca,[ ])3Ca6Mn3Zr3WSi(Si9O27)2(Si3O9)2(CO3)O(OH,Cl)2. The original formula was extended to show the presence of both the cyclic silicate groups and silicon at the M4 site, according to the nomenclature of the eudialyte group. It is the third eudialyte-group mineral with essential tungsten, and second with essential rare earth elements. In fact, some niobium substitutes for tungsten in johnsenite-(Ce). Other characteristic feature is the presence of essential carbonate group, shared with carbokentbrooksite, golyshevite, mogovidite and zirsilite-(Ce).

<span class="mw-page-title-main">Kentbrooksite</span> Mineral of the eudialyte group

Kentbrooksite is a moderately rare mineral of the eudialyte group, with chemical formula (Na,REE)15(Ca,REE)6Mn3Zr3NbSi[(Si9O27)2(Si3O9)2O2]F2·2H2O. This extended formula shows the presence of cyclic silicate groups and dominance of Si at the M4 site, according to the nomenclature of the eudialyte group. The characteristic features of kentbrooksite, that make it different from eudialyte are: (1) dominancy of fluorine (the only currently known example among the whole group), (2) dominancy of manganese, and (3) dominancy of niobium. Trace hafnium and magnesium are also reported. Kentbrooksite is relatively common when compared to most other species of the group.

Oneillite is a rare mineral of the eudialyte group with the chemical formula Na15Ca3Mn3Fe2+3Zr3NbSiO(Si3O9)2(Si9O27)2(O,OH,H2O)3(OH,Cl)2. The formula is based on the original one but extended to show the presence of cyclic silicate groups and domination of Si at the M4 site. The mineral has lowered symmetry (space group R3, instead of more specific for the group R3m one) due to Ca-Mn ordering. Similar feature is displayed by some other eudialyte-group members: aqualite, labyrinthite, raslakite, and voronkovite. Oneillite is strongly enriched in rare earth elements (REE, mainly cerium), but REE do not dominate any of its sites.

Reederite-(Y) is a rare mineral with the formula (Na,Mn,Fe)15(Y,REE)2(CO3)9(SO3F)Cl. It is the only known mineral with fluorosulfate (fluorosulfonate). "REE" in the formula stands for rare earth elements other than yttrium, that is mostly cerium, with traces of neodymium, dysprosium, lanthanum and erbium. The formula also includes a Levinson suffix "-(Y)" pointing to the dominance of yttrium at the corresponding site. Reederite-(Y) crystallizes in the hexagonal crystal system with the space group P6, rarely seen among minerals.

Sheldrickite is a sodium calcium carbonate fluoride mineral, named in honor of George M. Sheldrick, former Professor of Crystallography at the University of Göttingen in Germany. Sheldrick is the creator of SHELLX computer program widely used for the analysis of crystal structures. Determination of the structure of this mineral required the software's capability of handling twinned crystals.

References

  1. 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.
  2. Mineralienatlas.
  3. Donnayite-(Y) on Webmineral.
  4. Donnayite-(Y) on Handbook of Mineralogy.
  5. Donnayite-(Y) on Mindat.
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