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Eveslogite | |
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General | |
Category | Inosilicate |
Formula (repeating unit) | (Ca,K,Na,Sr,Ba) 48[(Ti,Nb,Fe,Mn) 12(OH) 12Si 48O 144](F,OH,Cl) 14 |
IMA symbol | Evl [1] |
Strunz classification | 9.DG.97 |
Crystal system | Monoclinic |
Crystal class | Prismatic (2/m) (same H-M symbol) |
Space group | P2/m |
Identification | |
Cleavage | perfect {001} and {010} |
Fracture | splintery |
Tenacity | brittle |
Mohs scale hardness | 5 |
Luster | vitreous to resinous; silky |
Streak | white and at times yellow-brown |
Density | 2.85 g/cm3 (meas.) 2.93 g/cm3 (calc.) |
Eveslogite is a complex inosilicate mineral with a chemical formula (Ca,K,Na,Sr,Ba)
48[(Ti,Nb,Fe,Mn)
12(OH)
12Si
48O
144](F,OH,Cl)
14 found on Mt. Eveslogchorr in Khibiny Mountains, on the Kola peninsula, Russia. It was named after the place it was found. This silicate mineral occurs as an anchimonomineral veinlet that cross-cuts poikilitic nepheline syenite. This mineral appears to resemble yuksporite, as it forms similar placated fine fibrous of approximately 0.05 to 0.005mm that aggregates outwardly. The color of eveslogite is yellow or rather light brown. In addition, it is a semitransparent mineral that has a white streak and a vitreous luster. Its crystal system is monoclinic and possesses a hardness (Mohs) of 5. This newly discovered mineral belongs to the astrophyllite group of minerals and contains structures that are composed of titanosilicate layers (Krivovichev et al., 2004). Limited information about this mineral exists due to the few research studies carried out since its recent discovery.
Eveslogite is a monoclinic-prismatic mineral that contains a trilogy of elements, which includes: aluminum, calcium, barium, chlorine, hydrogen, fluorine, manganese, iron, niobium, potassium, oxygen, silicon tantalum, sodium titanium and zirconium. It is usually found at Mount Eveslogchorr, Kola Peninsula, Khibina alkaline massif, in Russia. This mineral adds to the rapidly expanding class of the porous materials that are vital in gas separation, catalysis, optoelectronics, and in ion exchange processes. According to the article Crystal Research and Technology by Depmeier that seeks to further explain the properties of eveslogite, this mineral is in almost all aspect similar to yuksporite. However, when compared to yuksporite, eveslogite is much poorer in Ba content and it possesses different thermal capability. This mineral was discovered by Yuri Men’shikov in 1998.
Eveslogite is a complex titanosilicate made up of numerous elements including silicon, sodium, calcium and potassium. Its chemical formula is (Ca,K,Na,Sr,Ba)
48[(Ti,Nb,Fe,Mn)
12(OH)
12Si
48O
144](F,OH,Cl)
14, with the number of atoms in the chemical formula being 298.4. The listed elements in the formula are Ba, Cl, Ca, Fe, F, H, K, Mn, O, Sr, Si and Ti. The table below shows the composition of elements and their relative weight.
Element | Symbol | Weight% | Atoms | Atoms% | Atom weight (u) | Sum weight (u) |
---|---|---|---|---|---|---|
Hydrogen | H | 0.29 | 20.4 | 6.84 | 1.0079470 | 20.5621188 |
Oxygen | O | 37.28 | 164.4 | 55.09 | 15.9994300 | 2,630.3062920 |
Fluorine | F | 1.13 | 4.2 | 1.41 | 18.9984033 | 79.7932937 |
Sodium | Na | 1.56 | 4.8 | 1.61 | 22.9897702 | 110.3508970 |
Silicon | Si | 19.11 | 48 | 16.09 | 28.0855300 | 1,348.1054400 |
Chlorine | Cl | 0.70 | 1.4 | 0.47 | 35.4532000 | 49.6344800 |
Potassium | K | 6.65 | 12 | 4.02 | 39.0983100 | 469.1797200 |
Calcium | Ca | 14.99 | 26.4 | 8.85 | 40.0784000 | 1,058.0697600 |
Titanium | Ti | 4.48 | 6.6 | 2.21 | 47.8671000 | 315.9228600 |
Manganese | Mn | 0.47 | 0.6 | 0.20 | 54.9380499 | 32.9628299 |
Iron | Fe | 0.95 | 1.2 | 0.40 | 55.8452000 | 67.0142400 |
Strontium | Sr | 2.98 | 2.4 | 0.80 | 87.6210000 | 210.2904000 |
Niobium | Nb | 4.74 | 3.6 | 1.21 | 92.9063820 | 334.4629752 |
Barium | Ba | 4.67 | 2.4 | 0.80 | 137.3277000 | 329.5864800 |
In addition, this mineral has the empirical formula Ca22.46K12.27Na10.3Sr1.8Ba1.25Ti5.53Nb3.34Mn3+0.95Fe2+0.83Fe3+0.2Zr0.19Rb0.14Ta0.08 (OH)12Si47.3Al0.41O138.08(OH)9.42Cl0.8 and a molecular weight of 6,800.28 grams. Due to this form of composition, eveslogite’s structure has been observed to resist characterization because of its poor diffraction of its crystals and also due to its small dimensions (Chukanov et al., 2008). The aspect of characterization has been made possible after the late 20th century discovery of the 3rd generation X-ray synchrotron sources that made it possible to structurally characterize various mineral elements that could not have been characterized using the in-house X-ray sources (Burzo, 2006).
Eveslogite is a titanosilicate mineral that falls under the group of astrophyllite and fits within the point and space group P2/m {P1 1 2/m} {P2/m} {P1 2/m 1}. It is a mineral that is light brown or yellowish in color. It has a silky structure with white streak. Its tenacity is brittle and an indistinctly perfect cleavage of {001} and {010}. In regard to its general appearance, as explained by Chukanov et al. 2008, this mineral is indistinguishable from yuksporite and other related titanosilicate. In addition, the article American Mineralogist further expounds on both the measured and calculated densities of this mineral. After measuring the density of eveslogite it recorded a total of 2.85 g/cm3 but when directly calculated, it recorded a slightly higher density of 2.93 g/cm3. Additionally, the physical characteristics of eveslogite include a fracture that is largely splintery and a rough semitransparent gold like appearance.
The structure of eveslogite is based upon complex rods that consist of the corner sharing octahedral (TiO) and the tetrahedral SiO4. Due to its 5- Apatite hardness and density of 2.85 the general structure of this mineral is a rigid but porous in nature just like other astrophyllite. Some of the minerals that are largely associated with Eveslogite in terms of close similarity of their structure include nepheline, biotite, fluorite, K-feldspar, eudialyte and also many other minerals that fall under the astrophyllite group. Eveslogite is an orthorhombic mineral that fits within the space group 2lm prismatic. Eveslogite structure of the titanosilicate rods is remarkably unique when compared with other tetrahedral silicates. This is because it consists of a total of nine distinct symmetry independent silicates, which includes; SilO4, Si4O4, and Si5O4 similar to the xonotlite double chains structure.
Although eveslogite has a rigid structure, the nanorods (Ti,Nb)
4(O,OH)
4[Si
6O
17]
2[Si
2O
7]
3 are porous. These internal pores in the structure of eveslogite are defined by eight-Membered rings (8MR) separated by two parallel channels of Si9O4 and Si4O7 tetrahedral groups (Krivovichev et al., 2004). On the other hand, the inside part of eveslogite titanosilicate nanorods is composed of alkali metals cations Na2,Nal, K1-K5 and the H2O molecules. In general, the composition of the structure, eveslogite, is especially in the discovery of the existence of titanosilicate nanorods in the composition of this mineral that provides a vital notion for further research and understanding of the structural diversity of Titanosilicate and other alkaline astrophyllite. However, at present, the individual crystal structure of the eveslogite minerals is well described in detail in the article of Geology of Ore Deposits (Chukanov et al. 2008).
The particles of eveslogite are found in Mt. Eveslogchorr in Khibiny Mountains, Kola Peninsula, Russia. In particular the geological occurrence of this mineral and the place of conservation for this mineral is Fersman Mineralogical Museum in Moscow Russia (Hawthorne 2012). Eveslogite derives its name from this locality, particularly from Mt. Evesglochorr. Since it is a newly discovered mineral, there has not been extensive research to show if it occurs in any significant amounts in other parts of the world.
Eveslogite often occurs in close proximity with other rare-earth minerals, particularly the other Astrophyllite mineral elements, in addition, intergrowths with particular orientations are frequently found. In regard to its geological setting. Eveslogite is commonly found in peralkaline granitoids, where it may be selectively included by certain major minerals (such as feldspar) or may form aggregates of multiple types of other minerals that are also found in the Russian mountain of Eveslogchorr.
Eveslogite synonym is IMA2001-023 and its axial ratios are; a:b:c =0.5641:1:1.7768. Among its special characteristics is that its estimated radioactivity is barely detectable. The radioactivity test in regard to eveslogite can be measured using GRapi=172.67 (Gamma Ray American Petroleum Institute Units). According to the research carried out by Krivovichev et al., the chemical composition of eveslogite was determined through a wavelength-dispersion spectrometry, which encompasses the Cameca MS-46 microbe electron that was operating at 20kV. This strategy was adopted because of the traditional test of bond lengths and the bond-valence analysis, resulting in errors and therefore could not result in reliable information. Through the use of the wavelength dispersion spectrometry approach, other special feature of the Eveslogite were that, the rods in the structure of the Eveslogite are separated by walls that appears to be parallel and acts as the main linkage of the rods to the 3-dimensional structure of this mineral. This is a special feature to this mineral since other minerals that fall into this Astrophyllite group do not possess these walls in between their rods structure.
The pyroxenes are a group of important rock-forming inosilicate minerals found in many igneous and metamorphic rocks. Pyroxenes have the general formula XY(Si,Al)2O6, where X represents calcium (Ca), sodium (Na), iron or magnesium (Mg) and more rarely zinc, manganese or lithium, and Y represents ions of smaller size, such as chromium (Cr), aluminium (Al), magnesium (Mg), cobalt (Co), manganese (Mn), scandium (Sc), titanium (Ti), vanadium (V) or even iron. Although aluminium substitutes extensively for silicon in silicates such as feldspars and amphiboles, the substitution occurs only to a limited extent in most pyroxenes. They share a common structure consisting of single chains of silica tetrahedra. Pyroxenes that crystallize in the monoclinic system are known as clinopyroxenes and those that crystallize in the orthorhombic system are known as orthopyroxenes.
Silicate minerals are rock-forming minerals made up of silicate groups. They are the largest and most important class of minerals and make up approximately 90 percent of Earth's crust.
Zussmanite is a hydrated iron-rich silicate mineral with the chemical formula K(Fe2+,Mg,Mn)13[AlSi17O42](OH)14. It occurs as pale green crystals with perfect cleavage.
Yuksporite is a rare inosilicate mineral with double width, unbranched chains, and the complicated chemical formula K4(Ca,Na)14Sr2Mn(Ti,Nb)4(O,OH)4(Si6O17)2(Si2O7)3(H2O,OH)3. It contains the relatively rare elements strontium, titanium and niobium, as well as the commoner metallic elements potassium, calcium, sodium and manganese. As with all silicates, it contains groups of linked silicon and oxygen atoms, as well as some associated water molecules.
Tienshanite, named for the Tian Shan Range in Mongolia, is a rare borosilicate mineral, though rock-forming in some parts of its original locality at the Dara-i-Pioz Glacier in Tajikistan. Its formula is extremely complex: KNa3(Na,K,[])6(Ca,Y,RE)2Ba6(Mn2+,Fe2+,Zn,Ti)6(Ti,Nb)6Si36B12O114[O5.5(OH,F)3.5]F2.
Alluaivite is a rare mineral of the eudialyte group, with complex formula written as Na19(Ca,Mn)6(Ti,Nb)3Si26O74Cl·2H2O. It is unique among the eudialyte group as the only titanosilicate (other representatives of the group are usually zirconosilicates). The two dual-nature minerals of the group, being both titano- and zirconosilicates, are labyrinthite and dualite. They both contain alluaivite module in their structures. Alluaivite is named after Mt. Alluaiv in Lovozero Tundry massif, Kola Peninsula, Russia, where it is found in ultra-agpaitic, hyperalkaline pegmatites.
Eudialyte group is a group of complex trigonal zircono- and, more rarely, titanosilicate minerals with general formula [N(1)N(2)N(3)N(4)N(5)]3[M(1a)M(1b)]3M(2)3M(4)Z3[Si24O72]O'4X2, where N(1) and N(2) and N(3) and N(5) = Na+ and more rarely H3O+ or H2O, N(4) = Na+, Sr2+, Mn2+ and more rarely H3O+ or H2O or K+ or Ca2+ or REE3+ (rare earth elements), M(1) and M(1b) = Ca2+, M(1a) = Ca2+ or Mn2+ or Fe2+, M(2) = Fe (both II and III), Mn and rarely Na+, K+ or Zr4+, M(3) = Si, Nb and rarely W, Ti and [] (vacancy), M(4) = Si and or rarely [], Z Zr4+ and or rarely Ti4+, and X = OH−, Cl− and more rarely CO32− or F−. Some of the eudialyte-like structures can even be more complex, however, in general, its typical feature is the presence of [Si3O9]6− and [Si9O27]18− ring silicate groups. Space group is usually R3m or R-3m but may be reduced to R3 due to cation ordering. Like other zirconosilicates, the eudialyte group minerals possess alkaline ion-exchange properties, as microporous materials.
Alsakharovite-Zn (IMA symbol: Ask-Zn) is an extremely rare alkaline strontium zinc titanium silicate mineral from the cyclosilicates class, with the chemical formula NaSrKZn(Ti,Nb)4(Si4O12)2(O,OH)4·7H2O, from alkaline pegmatites. It belongs to the labuntsovite group.
Cervandonite is a rare arsenosilicate mineral. It has a chemical formula (Ce,Nd,La)(Fe3+
,Fe2+
,Ti4+
,Al)
3SiAs(Si,As)O
13 or (Ce,Nd,La)(Fe3+
,Fe2+
,Ti,Al)
3O
2(Si
2O
7)(As3+
O
3)(OH). It has a monoclinic crustal structure with supercell (Z=6), the crystal structure was established as a trigonal subcell, with space group R3m and a = 6.508(1)Ǻ, c = 18.520(3) Ǻ, V 679.4(2) Ǻ3, and Z=3. It was first described by Buhler Armbruster in 1988, but it has proven to be problem due to the extreme scarcity of single crystals and its unusual replacement of silicon and arsenic. Cervandonite is named after the location where it was first described, Pizzo Cervandone (Scherbadung), Italy in the Central Alps.
Nabalamprophyllite has a general formula of Ba(Na,Ba){Na3Ti[Ti2O2Si4O14](OH,F)2}. The name is given for its composition and relation to other lamprophyllite-group minerals. Lamprophyllite is a rare Ti-bearing silicate mineral usually found in intrusive igneous rocks.
Jonesite is a mineral with the chemical formula Ba4(K,Na)2[Ti4Al2Si10O36]*6H2O. This mineral is named after Francis Tucker Jones (1905–1993), who discovered the mineral while working as a Research Chemical Microscopist at Berkeley in CA. Jonesite has diffraction symmetry of mmm, which implies an orthorhombic system with all three axes perpendicular to each other and the angles between each axis equal to 90 degrees. In addition to symmetrical properties, Jonesite is a biaxial mineral with birefringence, which is a term to describe the difference between index of refraction. Jonesite is anisotropic, meaning the speed of light changes through the mineral, so the mineral shows color when viewed in crossed polarized light under a microscope. The mineral also has medium relief, which is a measure of how well the mineral stands out when viewed under a microscope in plane polarized light. In addition to being one of the rarest minerals in the Benitoite Gem mine located in California, Jonesite also is the first titanosilicate mineral with a porous double-layered crystal structure. This discovery is important because titanosilicate frameworks have industrial uses in energy companies and are used in containing radioactive waste.
This list gives an overview of the classification of minerals (silicates) and includes mostly International Mineralogical Association (IMA) recognized minerals and its groupings. This list complements the List of minerals recognized by the International Mineralogical Association series of articles and List of minerals. Rocks, ores, mineral mixtures, non-IMA approved minerals and non-named minerals are mostly excluded.
Ikranite is a member of the eudialyte group, named after the Shubinov Institute of Crystallography of the Russian Academy of Sciences. It is a cyclosilicate mineral that shows trigonal symmetry with the space group R3m, and is often seen with a pseudo-hexagonal habit. Ikranite appears as translucent and ranges in color from yellow to a brownish yellow. This mineral ranks a 5 on Mohs Scale of Hardness, though it is considered brittle, exhibiting conchoidal fracture when broken.
Andrianovite is a very rare mineral of the eudialyte group, with formula Na12(K,Sr,Ce)6Ca6(Mn,Fe)3Zr3NbSi(Si3O9)2(Si9O27)2O(O,H2O,OH)5. The original formula was extended to show the presence of cyclic silicate groups and silicon at the M4 site, according to the nomenclature of eudialyte group. Andrianovite is unique among the eudialyte group in being potassium-rich (other eudialyte-group species with essential K are davinciite and rastsvetaevite). It is regarded as potassium analogue of kentbrooksite, but it also differs from it in being oxygen-dominant rather than fluorine-dominant. Also, the coordination number of Na in this representative is enlarged from 7 to 9. The name of the mineral honors Russian mathematician and crystallographer Valerii Ivanovich Andrianov.
Dualite is a very rare and complex mineral of the eudialyte group, its complexity being expressed in its formula Na
30(Ca,Na,Ce,Sr)
12(Na,Mn,Fe,Ti)
6Zr
3Ti
3MnSi
51O
144(OH,H
2O,Cl)
9. The formula is simplified as it does not show the presence of cyclic silicate groups. The name of the mineral comes from its dual nature: zircono- and titanosilicate at once. Dualite has two modules in its structure: alluaivite one and eudialyte one. After alluaivite and labyrinthite it stands for third representative of the eudialyte group with essential titanium.
Labyrinthite is a very rare mineral of the eudialyte group. When compared to other species in the group, its structure is extremely complex - with over 100 sites and about 800 cations and anions - hence its name, with its complexity expressed in its chemical formula (Na,K,Sr)35Ca12Fe3Zr6TiSi51O144(O,OH,H2O)9Cl3. The formula is simplified as it does not show the presence of cyclic silicate groups. Complexity of the structure results in symmetry lowering from the typical centrosymmetrical group to R3 space group. Other eudialyte-group representatives with such symmetry lowering include aqualite, oneillite, raslakite, voronkovite. Labyrinthite is the second dual-nature representative of the group after dualite and third with essential titanium after dualite and alluaivite.
Feklichevite is a rare mineral of the eudialyte group with the formula Na11Ca9(Fe3+,Fe2+)2Zr3NbSi(Si3O9)2(Si9O27)2. The original formula was extended to show the presence of cyclic silicate groups and presence of silicon at the M4 site, according to the nomenclature of eudialyte group. When compared to other minerals of the group, feklichevite characterizes in the presence of ferric iron (thus similar to ikranite, mogovidite and fengchengite) and dominance of calcium at the N4 site. Calcium is ordered in the structure and is also present at the M1 site. Other iron-bearing minerals of the group are eudialyte, ferrokentbrooksite, georgbarsanovite, khomyakovite, labyrinthite, oneillite and rastsvetaevite, but they rather contain ferrous iron Feklichevite name honors Russian mineralogist and crystallographer, V. G. Feklichev.
Raslakite is a rare mineral of the eudialyte group with the chemical formula Na15Ca3Fe3(Na,Zr)3Zr3(Si,Nb)SiO(Si9O27)2(Si3O9)2(OH,H2O)3(Cl,OH). This formula is based on the original one, and is extended to show the presence of cyclic silicate groups. The additional silicon and oxygen shown in separation from the cyclic groups are in fact connected with two 9-fold rings. The mineral has lowered symmetry, similarly to some other eudialyte-group members: aqualite, labyrinthite, oneillite and voronkovite. The specific feature of raslakite is, among others, the presence of sodium and zirconium at the M2 site. Raslakite was named after Raslak Cirques located nearby the type locality.
Jinshajiangite is a rare silicate mineral named after the Jinshajiang river in China. Its currently accepted formula is BaNaFe4Ti2(Si2O7)2O2(OH)2F. It gives a name of the jinshajiangite group. The mineral is associated with alkaline rocks. In jinshajiangite, there is a potassium-to-barium, calcium-to-sodium, manganese-to-iron and iron-to-titanium diadochy substitution. Jinshajiangite is the iron-analogue of surkhobite and perraultite. It is chemically related to bafertisite, cámaraite and emmerichite. Its structure is related to that of bafertisite. Jinshajiangite is a titanosilicate with heteropolyhedral HOH layers, where the H-layer is a mixed tetrahedral-octahedral layer, and the O-layer is simply octahedral.
Lamprophyllite is a rare, but widespread mineral Ti-silicate mineral usually found in intrusive agpasitic igneous rocks. Yellow, reddish brown, Vitreous, Pearly.