1 / 34

Mineral/Crystal Chemistry and Classification of Minerals Revisited

Mineral/Crystal Chemistry and Classification of Minerals Revisited. Coordination, Solid Solution, Polymorphs and Isomorphs, Mineral Classes . Mineral and Crystal Chemistry. Minerals have:

lori
Télécharger la présentation

Mineral/Crystal Chemistry and Classification of Minerals Revisited

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Mineral/Crystal Chemistry and Classification of Minerals Revisited Coordination, Solid Solution, Polymorphs and Isomorphs, Mineral Classes

  2. Mineral and Crystal Chemistry Minerals have: • Characteristic geometric arrangement or structure of constituent atoms that is regular and repeating in a 3-D arrangement (CRYSTALLINE SOLID) • Arrangement of atoms depends on their ionic radius and valence • Many minerals can be conceptualized as anions (or anion complexes) tightly packed together with cations filling in the intervening spaces (COORDINATION POLYHEDRA) • Fixed or fixed range of chemical composition (FORMULA) • Substitution of one element for another (SOLID SOLUTION) • Depends on their ionic radius and valence • Substitution may be complete or limited, simple or coupled, and varies with P-T conditions

  3. Ionic radius (IR) and Valence Cations (+) —> generally smaller IR Anions (-) —> generally larger IR Variable dependant on atomic number and interaction with other ions Atomic Theory

  4. The Coordination Principle:Geometry of Atomic Building Blocks • In an ionically bonded substance (all minerals for our purposes) cations are surrounded by anions (or anionic complexes) • In stable mineral crystals • The number and arrangement of anions surrounding a cation forms a Coordination polyhedron

  5. The Coordination Principle Coordination polyhedron • If all atoms are the same size, they can be packed together so that each atom touches 12 others (Hexagonal or Cubic closest packing)

  6. The Coordination Principle Coordination polyhedron • BUT atoms vary in size • So the size and shape of the coordination polyhedron is determined by the ionic radii of the cation and anion (anion complex) involved • Radius ratio (cation radius/anion radius) • This shape is described by the number of anions surrounding a cation: Coordination number (C.N.)

  7. Coordination Polyhedron A. Triangular (CN = 3) B. Tetrahedral (CN 4) C. Octahedral (CN 6) D. Cubic (CN 8) E. Dodecahedral (CN 12)

  8. The Coordination Principle • Oxygen (O-2) is the most common anion in coordination polyhedron • Cations coordinate with oxygen in predicable ways (see Ch. 4, p. 10) • Minerals have specific physical locations (sites) that can hold only a few types of ions • Each site has specific coordination polyhedron type

  9. The Coordination Principle • Coordination explains anion groups • O is more tightly bonded to central, highly charged cation than to other cations • Examples: • C+4 in triangular coordination (CN = 3) produces (CO3)-2 • S+6 in tetrahedral coordination (CN = 4) produces (SO4)-2 • Si+4 in tetrahedral coordination (CN = 4) produces (SiO4)-4

  10. Formula reflects the proportions of elements (cations and anions) present in the mineral Common conventions: Subscripts indicate atomic proportions; superscripts indicate charge Commas for either-or; ex: olivine [(Mg,Fe)2SiO4] Anion complexes typically in parentheses; ex: dolomite [CaMg(CO3)2] Historically determined by wet chemical techniques Modern techniques typically use focused energy beam (electron or ion microprobe) Reported at wt% of elements or oxides Must be converted to atomic proportions Mineral Formulas

  11. Mineral Formulas: Recalculation • Formula = CuFeS2 • Converts wt% of elements or oxides into a mineral formula (pure substance or solid solution) *Calculated by wt%/atomic wt Ex for Cu: 34.30/63.54 = 0.5398 **Normalized to make the smallestnumber equivalent to 1

  12. 100% C 0% B 100% B 100% A 0% A 100% B 100% A Mineral Formulas: Graphical Representation • Can show relative proportions of elements in a mineral • In wt%, oxide wt%, or atomic proportions • Especially useful in showing multi-component systems and solid solution systems Three components Two components

  13. Mineral Formulas: Graphical Representation • Example: • CaO – MgO – SiO2 system

  14. Atomic Substitution/Solid Solution • Homogeneous crystalline solids of variable chemical composition • Many minerals vary in their composition • Elements are readily substituted (atomic substitution) for one another in many crystal structures, when certain conditions are met

  15. Atomic Substitution/Solid Solution Requires: • Valences of substituting ions are no more different than 1 • Na+1 for Ca+2 • Al+3 for Si+4 • Difference in the size of substituting ions must be <15% (at room temperature)

  16. Some substitutions involve complete solid solution Involves ions of (nearly) equal charge and size Any composition (mixture) may occur between end member compositions Examples: Olivine series: Forsterite (Mg2SiO4 ) to Fayalite (Fe2SiO4) Plagioclase feldspar series: Albite (NaAlSi3O8) to Anorthite (CaAl2Si2O8) Atomic Substitution/Solid Solution

  17. Some substitutions involve partial or limited solid solution Involve ions of different sizes or charges Limited compositions (mixtures) may occur between end members Examples: Carbonates: Limited solid solution between Calcite (CaCO3) to Dolomite [CaMg(CO3)2] and Magnesite (MgCO3) to Dolomite Pyroxene group: Limited solution between Hypersthene (MgSiO3) and Diopside (CaMgSi2O6) Atomic Substitution/Solid Solution

  18. Some substitutions are simple 1 for 1 substitution of ions of equal charge Some substitutions are coupled Substitution involves 2 or more ions Necessary to balance different charges Examples: Carbonates: Simple solid solution between Magnesite (MgCO3) and Siderite (FeCO3) Plagioclase feldspar: Coupled solution between Albite (NaAlSi3O8) to Anorthite (CaAl2Si2O8) Atomic Substitution/Solid Solution

  19. Atomic substitution is greater at higher temperature (crystal lattices are more open) and can accommodate greater ionic radius deviation (than 15%) Na+1 IR = 0.97 K+1 IR = 1.33 Ca+2 IR = 0.99 Solid Solution & T-P Controls • Atomic substitution is greater at higher pressure because it can change the size of crystallographic sites and ions, thus accommodate greater ionic radius deviation

  20. Pyrite, FeS2 (Fe+2S2), Cubic Marcasite, FeS2 (Fe+2S2), Orthorhombic Polymorphism • The same chemical formula applies to two (or more) distinct mineral species • Chemical composition may not be sufficient to designate a specific mineral species (physically homogeneous and separable portion of a material system) • Polymorphs have different crystal forms (atomic arrangements) and different physical properties • Different polymorphs occur as a result of differing environmental conditions, principally temperature and pressure

  21. Polymorphs • Examples: • Diamond and Graphite (C); Diamond Graphite Geobarometer: (determines pressure of formation)

  22. Polymorphs • Examples: • Quartz, Tridymite, and Cristobolite (SiO2); Tridymite Quartz Cristobalite

  23. Polymorphs • Example: • Calcite and Aragonite (CaCO3); Calcite Aragonite

  24. Isomorphism (Isostructuralism) • Minerals with analogous formulas where the relative sizes of cations and anions are similar and crystal structure is identical or closely related • Typically (but not always) the basis for grouping and classification, e.g. • Garnet group, Amphibole group, Mica group, Pyroxene group Galena, PbS Halite, NaCl

  25. Isomorphism • Anions and cations of isomorphic minerals have • The same relative size • The same coordination • Crystallize in the same crystal structure • Share similarity of crystal structure but not (necessarily) chemical behavior • Ex: Halite and galena Galena, PbS Halite, NaCl

  26. Isomorphism • Some isomorphic minerals share closely related formulas and identical crystal structures • Ex: Aragonite (orthorhombic) and Calcite (trigonal) Groups

  27. Some isomorphic minerals have such similar compositions and structures that they form solid solution Complete solid solution between Albite (NaAlSi3O8) and Anorthite (CaAl2Si2O8 ) Limited solid solution between Calcite (CaCO3) and Magnesite (MgCO3) Isomorphism and solid solution are distinct though related concepts Isomorphism and Solid Solution • Some isomorphic minerals do not have solid solution; Ex: Halite (NaCl) and Galena (PbS) • Some solid solutions do not have isomorphic end members; Ex: Sphalerite (Zn, Fe)S (cubic) and Pyrrhotite Fe1-xS (hexagonal) Sphalerite Pyrrhotite

  28. Class (chemical - anion complex) Subclass (atomic structure) Group (chemical and structural) Species (individual mineral – name) Variety (specific variation) Hierarchy of Mineral Classification • Class: Silicate (SiO44-) • Subclass: Tektosilicate (framework) • Group: Plagioclase Series (An-Ab) • Species: Oligoclase (70-90% Ab) • Variety: Sunstone (red-orange gemstone)

  29. Hierarchy of Mineral Classification: Mineral Classes • Based on the anion or anionic complexes in the crystal structure • Types of bonding and structures are the same (or similar) • Physical properties can be very similar within classes

  30. Mineral Subclasses Classified on basis of structure Example: silicates Nesosilicates: SiO4, independent silica tetrahedra Sorosilicates: Si2O7, double silica tetrahedra Cyclosilicates: SiO3, ring of silica tetrahedra Inosilicates: Si4O11, chains of silica tetrahedra Phyllosilicates: Si2O5, sheets of silica tetrahedra Tektosilicates: Si02, frameworks of silica tetrahedra Hierarchy of Mineral Classification

  31. Hierarchy of Mineral Classification • Mineral Groups; mineral species with close chemical and structural relationship e.g. (typically due to atomic substitution/solid solution) • Example: Amphibole, Feldspar, Mica, Pyroxene, Garnet, Olivine, Spinel

  32. Hierarchy of Mineral Classification Mineral Species • “naturally occurring homogeneous crystalline substance of inorganic origin, possessing characteristic physical properties, with either definite chemical composition or range in composition between certain limits” • Example: Plagioclase Group (Series) • Albite: NaAlSi308 • Oligoclase • Andesine • Labradorite • Bytownite • Anorthite: CaAl2Si2O8

  33. Hierarchy of Mineral Classification Mineral Variety • Slight variation in trace (non-structural) element content and resultant distinctive physical properties (typically color) • Corundum —> Ruby (red), Sapphire (blue) [AL2O3] • Classification tending to move away from species and variety names to names using a modifier of main species, e.g. • Fe in magnesite (MgCO3) —> ferroan magnesite Ruby Sapphire

  34. Collaborative Activity In groups, answer the following. Show all calculations. • Predict the coordination number (CN) and name the coordination polyhedron for each of the following cation-anion pairs: A. Zn (0.6Å) – S (1.84Å) B. Rb (1.61Å) – Cl (1.81Å) • The handout has two analyses of the mineral ilmenite. A. For analysis #1, convert the given weight proportions into atomic proportions and calculate the mineral formula B. Analysis #2 shows that a bit of solid solution is possible in the ilmenite structure, with Mg and/or Mn substituting for Fe. Calculate the formula for this analysis • Plot the following compositions on the TiO2-FeO-Fe2O3 diagram: Ilmenite (from analysis #1), Rutile (TiO2), Hematite (Fe2O3), Magnetite (Fe3O4), and Ulvöspinel (Fe2TiO4) • Plot the following compositions on the same diagram: A. 10% TiO2, 10% FeO, 80% Fe2O3 B. 40% TiO2, 25% FeO, 35% Fe2O3

More Related