Fluorellestadite
Fluorellestadite is a rare nesosilicate of calcium, with sulfate and fluorine, with the chemical formula Ca10(SiO4)3(SO4)3F2.[1] It is a member of the apatite group, and forms a series with hydroxylellestadite.
| Fluorellestadite | |
|---|---|
Fluorellestadite on blue calcite from the Crestmore Quarries, California, US | |
| General | |
| Category | Nesosilicates Apatite structural group |
| Formula (repeating unit) | Ca10(SiO4)3(SO4)3F2[1] |
| IMA symbol | Fel[2] |
| Strunz classification | 9.AH.25 (10 ed) 8/B.27-10 (8 ed) |
| Dana classification | 52.04.09.03 |
| Crystal system | Hexagonal |
| Crystal class | Dipyramidal (6/m) H-M symbol: (6/m) |
| Space group | P63/m |
| Identification | |
| Formula mass | 503.55 g/mol |
| Color | Light red, yellow, bluish green or colorless |
| Crystal habit | Acicular or hexagonal prismatic crystals, and fine-grained aggregates |
| Cleavage | Imperfect on {0001} |
| Fracture | Conchoidal |
| Tenacity | Very brittle |
| Mohs scale hardness | 4+1⁄2 |
| Luster | Sub-resinous to vitreous[3] |
| Streak | White with a weak bluish tint |
| Diaphaneity | Transparent to translucent |
| Specific gravity | 3.03 to 3.07 |
| Optical properties | Uniaxial (-) |
| Refractive index | nω = 1.638(2), nε = 1.632(2);[4] nω = 1.655, nε = 1.650[5] |
| Solubility | Easily soluble in dilute hydrochloric and nitric acids[3] |
| Other characteristics | Sometimes fluorescent. Not radioactive. |
| References | [6][7][8][9] |
Etymology edit
The mineral was originally named wilkeite by Eakle and Rogers in 1914, in honor of R. M. Wilke, a mineral collector and dealer.[3] In 1922, a sample of “wilkeite” was analysed and found to be sufficiently different from the material reported by Eakle and Rogers to consider it a new species.[5] The name “ellestadite” was proposed, in honor of Reuben B Ellestad (1900–1993), an American analytic chemist from the Laboratory for Rock Analysis, University of Minnesota, US.[5]
In 1982 Rouse and Dunn showed that the Si:S ratio was close to 1:1, giving the formula Ca10(SiO4)3(SO4)3X2, where X represents fluorine (F), hydroxyl (OH) or chlorine (Cl), and they named minerals in this group the ellestadite group.[10] The end members of the group were named hydroxylellestadite (X = OH), fluorellestadite (X = F) and chlorellestadite (X = Cl); ideal end-member chlorellestadite is assumed not to exist in nature, although it has been synthesized.[7] Wilkeite was discredited as a unique species, as it is not an end member of any solid solution series, but an intermediate member.[10]
The name fluorellestadite was changed to ellestadite-(F) in 2008[11] and changed back to fluorellestadite in 2010.[12]
Structure edit
The ellestadites are nesosilicates, which are minerals with isolated SiO4 tetrahedra. They are members of the apatite group, but whereas phosphorus is one of the chief constituents of apatite, in ellestadite it is almost completely replaced by sulfur and silicon, without appreciably altering the structure.[5] The crystal class is hexagonal 6/m, space group P63/m. The tetrahedral groups are arranged to create the 63 screw axis, and the fluorine atoms are located in channels parallel to this direction.[6] Some sources give unit cell parameters for one formula unit per unit cell (Z = 1), but some scientists consider the formula to be half the value accepted by the International Mineralogical Association (IMA), i.e. Ca5((Si,S)O4))3F, with two formula units per unit cell (Z = 2). Cell parameters for natural, as opposed to synthetic, material are a = 9.41 to 9.53 Å, and c = 6.90 to 6.94 Å. Rouse and Dunn postulated a hypothetical pure end-member with a = 9.543 Å and c = 6.917 Å.[10] Synthetic material has a = 9.53 to 9.561 Å, and c = 6.91 to 6.920 Å.[6]
Appearance edit
Fluorellestadite occurs as acicular or hexagonal prismatic, poorly terminated crystals, and as fine-grained aggregates.[4][9] Crystals are transparent and aggregates are translucent.[4] Material from Crestmore, California, is light rose-red or yellow in color,[3][6][7] and typically occurs in a matrix of blue calcite. Material from Russia is pale bluish-green or colorless.[4][9] The streak is white with a weak bluish tint, and the luster is sub-resinous on broken surfaces, but very brilliant on prism faces.[3]
Physical properties edit
Fluorellestadite shows imperfect cleavage perpendicular to the long crystal axis.[3][7] The mineral is very brittle, and breaks with a conchoidal fracture.[4] Its hardness is 4+1⁄2, between that of fluorite and apatite, and its specific gravity is 3.03 to 3.07, similar to that of fluorite. It is easily soluble in dilute hydrochloric and nitric acids[3] and is not radioactive.[8] When intensely heated, ellestadite (wilkeite) becomes colorless and then assumes a pale bluish green color on cooling.[3]
The mineral is uniaxial (-), with refractive indices nω = 1.638 to 1.655 and nε = 1.632 to 1.650.[4][5] It is sometimes fluorescent, white to blue-white or yellow-white in short-wave ultraviolet light, and medium white-yellow-brown or weak white in long-wave light.[6][8]
Occurrence and associations edit
The type locality is Coal Mine No. 44, Kopeisk, Chelyabinsk coal basin, Chelyabinsk Oblast, Southern Urals, Russia,[7] and type material is held at the Fersman Mineralogical Museum, Academy of Sciences, Moscow, Russia.[4] Ellestadite is a skarn mineral. It occurs associated with diopside, wollastonite, idocrase, monticellite, okenite, vesuvianite, calcite and others at Crestmore, Riverside County, California, US.[5][6] At Crestmore a contact zone exists between crystalline limestone and granodiorite. The area was quarried for limestone in the early 1900s, revealing varied associations of metamorphic minerals, including ellestadite (named as wilkeite) with garnet, vesuvianite and diopside, in blue calcite.[3] At the type locality it was formed in burned fragments of petrified wood in coal dumps, associated with lime, periclase, magnesioferrite, hematite, srebrodolskite and anhydrite.[4][9] Ellestadite (wilkeite) is often altered to okenite.[3]
References edit
- ^ a b IMA Mineral List with Database of Mineral Properties. Rruff.info. Retrieved on 2011-06-22.
- ^ 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.
- ^ a b c d e f g h i j Eakle and Rogers (1914) American Journal of Science 37: 262–267 (as Wilkeite)
- ^ a b c d e f g h John J. Jambor and Jacek Puziewicz (1989) New Mineral Names American Mineralogist 74: 500, abstract of Chesnokov, Bazhenova and Bushmakin (1987) Zapiski Vses. Mineralog, Obshch 116:743 (in Russian)
- ^ a b c d e f Duncan McConnell (1937) The substitution of SiO4 – and SO4 – groups for PO4 -groups in the apatite structure; ellestadite, the end member American Mineralogist 22: 977–986
- ^ a b c d e f Richard V. Gaines (1997) Dana’s New Mineralogy 8th ed. Wiley ISBN 0-471-19310-0
- ^ a b c d e Fluorellestadite: Fluorellestadite mineral information and data. Mindat.org (2011-06-18). Retrieved on 2011-06-22.
- ^ a b c Ellestadite-(F) Mineral Data. Webmineral.com. Retrieved on 2011-06-22.
- ^ a b c d Handbook of Mineralogy. Handbook of Mineralogy. Retrieved on 2011-06-22.
- ^ a b c Roland C. Rouse and Pete J. Dunn (1982) A contribution to the crystal chemistry of ellestadite and the silicate sulfate apatites American Mineraleralogist 67: 90–96
- ^ Burke (2008) The Mineralogical Record 39: 131
- ^ Pasero, Marco; Kampf, Anthony R.; Ferraris, Cristiano; Pekov, Igor V.; Rakovan, John; White, Timothy J. (2010). "Nomenclature of the apatite supergroup minerals". European Journal of Mineralogy. 22 (2): 163–179. Bibcode:2010EJMin..22..163P. doi:10.1127/0935-1221/2010/0022-2022.
External links edit
- JMol