- Chondrodite
-
Not to be confused with Chondrite.
Chondrodite
Chondrodite from Franklin, New Jersey, USAGeneral Category Nesosilicates Chemical formula Mg5(SiO4)2F2 Strunz classification 8/B.04-20 or 9.AF.45 Dana classification 52.3.2b.2 Identification Molar mass 351.6 g Color Yellow, orange, red or brown, rarely colorless Crystal habit Typically anhedral masses or grains, or as plates flattened on {010}, {001} or {100}.[1] Crystal system Monoclinic 2/m Prismatic Twinning Simple or multiple twinning common on {001}, also reported on {105} and {305}.[1] Cleavage Poor to good on (001) Fracture Conchoidal to Uneven Tenacity Brittle Mohs scale hardness 6 to 6.5 Luster Vitreous to Greasy Streak Grey or Yellow Diaphaneity Translucent Specific gravity 3.1 to 3.26 Optical properties Biaxial(+) Refractive index nα = 1.592 - 1.643, nβ = 1.602 - 1.655, nγ = 1.619 - 1.675, Birefringence 0.027 - 0.032 Pleochroism X golden yellow to orange, Y and Z light yellow to almost colorless[2] Solubility Soluble in HCl and H2SO4 Other characteristics Some specimens fluoresce orange yellow under shortwave and orange under longwave UV. Not radioactive. References [3][4][5][6] Chondrodite is a nesosilicate mineral with formula (Mg,Fe)5(SiO4)2(F,OH,O)2. Although it is a fairly rare mineral, it is the most frequently encountered member of the humite group of minerals. It is formed in hydrothermal deposits from locally metamorphosed dolomite. It is also found associated with skarn and serpentinite. It was discovered in 1817 on Mt. Somma, part of the Vesuvius complex in Italy, and named from the Greek for "granule", which is a common habit for this mineral.
Contents
Formula
Mg5(SiO4)2F2 is the end member formula as given by the International Mineralogical Association,[7] molar mass 351.6 g. There is usually some OH in the F sites, however, and Fe and Ti can substitute for Mg, so the formula for the naturally occurring mineral is better written (Mg,Fe,Ti)5(SiO4)2(F,OH,O)2.[3]
Structure
The chondrodite structure is based on a slightly distorted hexagonal close packed array of anions O, OH and F with metal ions in the octahedral sites resulting in zigzag chains of M(O,OH,F)6 octahedra. Chains are staggered so that none of the independent tetrahedral sites occupied by Si has OH or F corners.[1] Half of the octahedral sites are filled by divalent cations, principally Mg, and one tenth of the tetrahedral sites are filled by Si. There are three distinct octahedra in the array: Fe is ordered in the M1 sites but not in the larger M2 and smaller M3 sites.[8] Ti is ordered in the M3 positions, which are the smallest, but Ti concentration appears never to exceed 0.5 atoms Ti per formula unit in natural specimens.[9] In the humite series Mg2+ is replaced by Fe2+, Mn2+, Ca2+ and Zn2+ in that order of abundance, though Mg2+ always predominates.[1]
Unit cell
Space Group: P21/b
Unit Cell Parameters:
Synthetic F end member a=7.80 Å, b=4.75 Å, c=10.27 Å, beta=109.2o.
Synthetic OH end member a=7.914 Å, b=4.752 Å, c=10.350 Å, beta=108.71o.
Natural chondrodite has a=7.867 to 7.905 Å, b=4.727 to 4.730 Å, c=10.255 to 10.318 Å, beta=109.0o to 109.33o. Z=2.Color
Chondrodite is yellow, orange, red or brown, or rarely colorless, but zoning of different color intensity is common, and intergrown plates of chondrodite, humite, clinohumite, forsterite and monticellite have been reported.[1]
Optical properties
Chondrodite is biaxial(+), with refractive indices variously reported as nα = 1.592 - 1.643, nβ = 1.602 - 1.655, nγ = 1.619 - 1.675, birefringence = 0.025 - 0.037, and 2V measured as 64° to 90°, calculated: 76° to 78°. Refractive indices tend to increase from norbergite to clinohumite in the humite group. They also increase with Fe2+ and Ti4+ and with (OH)- substituting for F-.[1] Dispersion: r > v.
Environment
Chondrite is found largely in metamorphic contact zones between carbonate rocks and acidic or alkaline intrusions where fluorine has been introduced by metasomatic processes. It is formed by the hydration of olivine, (Mg,Fe2+)2SiO4, and is stable over a range of temperatures and pressures that include those existing in a portion of the uppermost mantle.[10]
Titanian chondrodite has been found as inclusions in olivine in serpentinite in West Greenland, where it is associated with clinohumite, olivine, magnesite, magnetite and Ni-Co-Pb sulfides in a matrix of antigorite.
See also
References
- ^ a b c d e f Phillips, W R and Griffen, D T (1981) Optical Mineralogy, pages 142 to 144
- ^ European Journal of Mineralogy (2002) 14: 1027-1032
- ^ a b Gaines et al (1997) Dana's New Mineralogy Eighth Edition, Wiley
- ^ http://www.mindat.org/min-1027.html Mindat
- ^ http://webmineral.com/data/Chondrodite.shtml
- ^ http://rruff.geo.arizona.edu/doclib/hom/chondrodite.pdf
- ^ http://rruff.info/ima
- ^ American Mineralogist (1970): 55: 1182-1194
- ^ American Mineralogist (1979) 64:1027
- ^ Physics and Chemistry of Minerals (1999) 26: 297-303
Categories:- Magnesium minerals
- Iron minerals
- Humite group
- Monoclinic minerals
Wikimedia Foundation. 2010.