Pyroxene
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Pyroxene is a chemically complex group of silicate minerals with many variations. The generic formula for pyroxene is XY(Si,Al)2O6, with X and Y representing many types of elements. Pyroxene rocks can contain a mix of any of 20 different subgroups.
Contents
Abundance and distribution
- Pyroxene is the most abundant dark mineral at the surface (1, pg 363)
- Mare basalts = 40%-65% (5%-30% for a few samples) pyroxene
- Anorthositic rocks (highland) = 0%-40% pyroxene
- The pyroxene/plagioclase ratio in mature soil increases with decreasing grain size. (6, pg 249)
Physical properties
- Pyroxene is paramagnetic. This is because of the Fe2+.
Chemical composition
It is difficult to define pyroxene because there are so many variants. For example, pigeonite -(Ca,Mg,Fe)(Mg,Fe)Si2O6 - is referenced in the Apollo 11 and Apollo 15 samples. But pigeonite covers a range of minerals including the two main pyroxene minerals, ferrosilite (FeSiO3) and enstatite (MgSiO3). The pyroxene we need for iron will have either Fe+2Fe+2(Si,Al)2O6 or Fe+2Y(Si,Al)2O6, with Y being some other metal. It can get a bit confusing. The one constant is that all types of pyroxene contain silicon (Si).
One thing to remember is that there are two types of chemical formulas, empirical and molecular. Actually, there are several other types but let’s keep it simple. Empirical formulas show the simplest positive integer ratio of atoms in the compound. This means that Fe2Si2O6 becomes FeSiO3. This means that there is one Fe and one Si atom for each O atom. The molecular formula specifies exactly how many atoms are in the molecule, but not its structure. Fe2Si2O6 tells you that there is exactly 2 iron, 2 silicon, and 6 oxygen atoms making up that molecule. It can get confusing when the resource you are reading doesn’t specify which formula they are using.
Here’s how it breaks down (as far as I can figure out):
- Pyroxenes are usually represented by a mixing of the possible end members. (5, Chapter X,M)
- Enstatite (Mg2Si2O6) – Again, usually specified as MgSiO3.
- Ferrosilite (Fe2Si2O6) – In most of the literature it’s specified as FeSiO3. This is the pyroxene we want for iron production.
- Wollastonite (CaSiO3) – Pretty rare and not what we’re looking for right now.
- Pyroxenes are often reported as mole % of end members. For example, Wo2En80Fs18 has 2% wollastonite with 80% enstatite and 18% ferrosilite. (5, Chapter X,M)
- Pyroxenes also have 3 structural forms based on how much CaSiO3 they contain. (2, pg 19)
- Orthopyroxene have the lowest concentration of CaSiO3.
- Pigeonite [(Ca,Mg,Fe)(Mg,Fe)Si2O6] (low-calcium clinopyroxene) has the middle concentration of CaSiO3.
- Augite (high-calcium clinopyroxene) has the highest concentration of CaSiO3.
- All forms display a wide range of enstatite and ferrosilite, and accept large amounts of Al, Ti, Mn, Cr, and Na. (5, Chapter X,M)
Other Lunar pyroxene facts:
- Lunar pyroxenes show substantial subsolidus reduction (chemical changes to a rock while it’s hot but still solid)(1, pg 126). This can result in free iron (also called native iron) being formed in the rock.
- Oxidized iron Fe3+ (Fe2O3) is not present in Lunar pyroxenes (1, pg 122). This is due to the more reducing conditions (low oxygen partial pressure) in gases on Luna. This means that iron minerals that are common on Earth are rare or nonexistent on Luna. The reverse is also true.
- Mare pyroxenes are almost exclusively clinopyroxene (augite) derived from mare basalts. Mare pyroxenes show extreme compositional zoning. (6, pg 249).
- Highland pyroxenes are >1/3 orthopyroxene (mostly bronzites En85-En61) and clinopyroxene. (6, pg 249)
Other members of the pyroxene group include:
- Aegrine
- Diopside
- Hedenbergite
- Hypersthene
- Spodumene
Data
Analysis of pyroxene mare basalts (selected samples)(1, pg 157-159)
- Apollo 17 (High-Ti)(>9% TiO2)
- Iron oxide (FeO) by weight percent range: 8.10% - 19.10%
- Average FeO by percent weight = 14.16%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.25 – 0.50
- Apollo 11 (High-Ti)(>9% TiO2)(High-K)(>0.3% K2O)
- Iron oxide (FeO) by weight percent range: 12.00% - 45.80%
- Average FeO by percent weight = 2.90%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.28 – 0.95
- Apollo 11 (High-Ti)(>9% TiO2)(Low-K)(<0.11% K2O)
- Iron oxide (FeO) by weight percent range: 9.60% - 41.07%
- Average FeO by percent weight = 22.41%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.27 – 0.69
- Apollo 12 ilmenite (<10%MgO, >5% TiO2) (Low-Ti)(1.5-9% TiO2)
- Iron oxide (FeO) by weight percent range: 13.31% - 30.28%
- Average FeO by percent weight = 21.78%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.32 – 0.87
- Apollo 12 pigeonite [a form of pyroxene] (<10% MgO, <5% TiO2) (Low-Ti)(1.5-9% TiO2)
- Iron oxide (FeO) by weight percent range: 16.90% - 46.54%
- Average FeO by percent weight = 29.69%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.28 – 0.99
- Apollo 12 olivine (>10% MgO, <5% TiO2)(Low-Ti)(1.5-9% TiO2)
- Iron oxide (FeO) by weight percent range: 16.34% - 41.90%
- Average FeO by percent weight = 25.79%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.33 – 0.99
- Apollo 15 pigeonite [a form of pyroxene] (<10% MgO, <5% TiO2) (Low-Ti)(1.5-9% TiO2)
- Iron oxide (FeO) by weight percent range: 14.50% - 30.20%
- Average FeO by percent weight = 20.86%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.25 – 0.80
- Apollo 15 olivine (>10% MgO, <5% TiO2)(Low-Ti)(1.5-9% TiO2)
- Iron oxide (FeO) by weight percent range: 13.60% - 36.60%
- Average FeO by percent weight = 22.63%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.31 – 0.79
- Luna 16 (Aluminous, Low-Ti basalts)(>10% Al2O3, 2-5% TiO2)
- Iron oxide (FeO) by weight percent range: 13.27% - 38.67%
- Average FeO by percent weight = 25.97%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.36 – 0.87
- Apollo 14 (Aluminous, Low-Ti basalts)(>10% Al2O3, 2-5% TiO2)
- Iron oxide (FeO) by weight percent range: 18.60% - 30.32%
- Average FeO by percent weight = 24.46%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.33 – 0.97
- Apollo 14 VHK (Very High Potassium)(>0.6% K2O)(Aluminous, Low-Ti basalts) (>10% Al2O3, 2-5% TiO2)
- Iron oxide (FeO) by weight percent range: 15.17% - 19.07%
- Average FeO by percent weight = 17.39%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.35 – 0.42
- Luna 24 (Very Low-Ti basalts)(<1.5% TiO2)
- Iron oxide (FeO) by weight percent range: 16.95% - 43.35%
- Average FeO by percent weight = 30.15%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.45 – 0.99
- Apollo 17 (Very Low-Ti basalts)(<1.5% TiO2)
- Iron oxide (FeO) by weight percent range: 17.42% - 42.54%
- Average FeO by percent weight = 27.31%
- Ratio of iron to magnesium [Fe/(Fe+Mg)] range = 0.29 – 0.97
Abundance of Lunar pyroxene (percent by volume) (2, pg 20)
- Mare basalts = 40%-65% (5%-30% for a few samples)
- Anorthositic rocks (highland) = 0%-40%
- Fragmental breccias (>25 micrometers across) = 5%-30%
- Soils = 5%-20% (composition and amount resembles local rocks)
Analysis of Lunar pyroxenes for iron (percent by weight)(2, pg 20)
- Mare = 8.97%
- Highland = 15.42%
FeO concentrations in pyroxene (percent weight)(3, pg 29)
- High-Ti mare basalts = 8.1% - 45.8%
- Low-Ti mare basalts = 13.1% - 45.5%
- Highland rocks = 8.20% – 24.0%
Lunar samples % pyroxene (randomly selected) (7)
- Sample 10003 (Apollo 11 mare basalt) = 48.6-51.7%
- Sample 12015 (Apollo 12 mare basalt) = 13.6-43%
- Sample 14078 (Apollo 14 KREEP basalt) = 25.5%
- Sample 15261 (Apollo 15 soil) = 14%
- Sample 67747 (Apollo 16 highland basalt) = 8%
- Sample 70215 (Apollo 17 high-Ti mare basalt) = 41-58%