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Chemical Formulas Subscripts represent relative numbers of elements present (Parentheses) separate complexes or substituted elements Fe(OH)3 – Fe bonded.

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Presentation on theme: "Chemical Formulas Subscripts represent relative numbers of elements present (Parentheses) separate complexes or substituted elements Fe(OH)3 – Fe bonded."— Presentation transcript:

1 Chemical Formulas Subscripts represent relative numbers of elements present (Parentheses) separate complexes or substituted elements Fe(OH)3 – Fe bonded to 3 separate OH groups (Mg, Fe)SiO4 – Olivine group – mineral composed of % of Mg, 100-Mg% Fe Go over this example in detail – maybe get a few others together

2 Stoichiometry Some minerals contain varying amounts of 2+ elements which substitute for each other Solid solution – elements substitute in the mineral structure on a sliding scale, defined in terms of the end members – species which contain 100% of one of the elements Iintroduced binary diagrams before, use a ternary example – feldspar, get figure in here… Go over several examples in class – make sure students understand this – many mneral subclasses differ only in one or the other elemental substitution – garnet as an example may be good – isostructural, two sets of 3 with a ternary substitution Work into functional difference of solid solution – differentiate between minerals of solid solution and ones in which substitution is less interchangable – why the difference – is this a chemical or environmental reason?

3 Chemical heterogeneity
Matrix containing ions a mineral forms in contains many different ions/elements – sometimes they get into the mineral Ease with which they do this: Solid solution: ions which substitute easily form a series of minerals with varying compositions (olivine series  how easily Mg (forsterite) and Fe (fayalite) swap…) Impurity defect: ions of lower quantity or that have a harder time swapping get into the structure

4 Compositional diagrams
Fe3O4 magnetite FeO wustite Fe2O3 hematite A Fe O A1B2C3 C=50%, B=35%, C=15% A1B1C1 x A1B2C3 x B C

5 Fe Mg Si fayalite forsterite enstatite ferrosilite Fe Mg forsterite fayalite Pyroxene solid solution  MgSiO3 – FeSiO3 Olivine solid solution  Mg2SiO4 – Fe2SiO4

6 KMg3(AlSi3O10)(OH)2 - phlogopite
K(Li,Al)2-3(AlSi3O10)(OH)2 – lepidolite KAl2(AlSi3O10)(OH)2 – muscovite Amphiboles: Ca2Mg5Si8O22(OH)2 – tremolite Ca2(Mg,Fe)5Si8O22(OH)2 –actinolite (K,Na)0-1(Ca,Na,Fe,Mg)2(Mg,Fe,Al)5(Si,Al)8O22(OH) Hornblende Actinolite series minerals

7 Normalization Analyses of a mineral or rock can be reported in different ways: Element weight %- Analysis yields x grams element in 100 grams sample Oxide weight % because most analyses of minerals and rocks do not include oxygen, and because oxygen is usually the dominant anion - assume that charge imbalance from all known cations is balanced by some % of oxygen Number of atoms – need to establish in order to get to a mineral’s chemical formula Technique of relating all ions to one (often Oxygen) is called normalization

8 Normalization Be able to convert between element weight %, oxide weight %, and # of atoms What do you need to know in order convert these? Element’s weight  atomic mass (Si=28.09 g/mol; O=15.99 g/mol; SiO2=60.08 g/mol) Original analysis Convention for relative oxides (SiO2, Al2O3, Fe2O3 etc)  based on charge neutrality of complex with oxygen (using dominant redox species)

9 Normalization example
Start with data from quantitative analysis: weight percent of oxide in the mineral Convert this to moles of oxide per 100 g of sample by dividing oxide weight percent by the oxide’s molecular weight ‘Fudge factor’ from Perkins Box 1.5, pg 22: is process called normalization – where we divide the number of moles of one thing by the total moles  all species/oxides then are presented relative to one another

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