Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lecture 5 Crystal Chemistry Part 4: Compositional Variation of Minerals 1. Solid Solution 2. Mineral Formula Calculations.

Published byEliezer Wivell Modified over 9 years ago

Similar presentations

Presentation on theme: "Lecture 5 Crystal Chemistry Part 4: Compositional Variation of Minerals 1. Solid Solution 2. Mineral Formula Calculations."— Presentation transcript:

1 Lecture 5 Crystal Chemistry Part 4: Compositional Variation of Minerals 1. Solid Solution 2. Mineral Formula Calculations

2 Solid Solution in Minerals Where atomic sites are occupied by variable proportions of two or more different ions Dependent on:  Similar ionic size (differ by less than 15-30%)  Must have electrostatic neutrality  Atomic sites are more accommodating at higher temperatures … BUT as temperatures cool exsolution can occur

3 Types of Solid Solution 1) Substitutional Solid Solution Simple cationic or anionic substitution e.g. Olivine (Mg,Fe) 2 SiO 4 ; Sphalerite (Fe,Zn)S Coupled substitution e.g. Plagioclase (Ca,Na)Al (1-2) Si (3-2) O 8 (Ca 2+ + Al 3+ = Na + + Si 4+ ) neutrality preserved

4 Types of Solid Solution 2) Interstitial Solid Solution Occurrence of ions and molecules within large voids within certain minerals (e.g., Beryl) Beryl, arguably considered a ring silicate (a Cyclosilicate) Yellow, green (SiO 4 ) -4 Purple Be tetrahedra Blue Al +3 in voids

5 Types of Solid Solution 3) Omission Solid Solution Exchange of single higher charge cation for two or more lower charged cations which creates a vacancy (e.g. Pyrrhotite Fe (1-x) S) with x = Fe ++ ranging 0-0.2 within regions of the crystal Where Fe +2 absent from some octohedral sites, some Iron probably Fe +3 to restore electrical neutrality Two Ferric Fe +3 ions balance charge for each three missing Ferrous Fe +2 ion

6 Mineral Formula Calculations  Chemical analyses are usually reported in weight percent of elements or elemental oxides  To calculate mineral formula requires transforming weight percent into atomic percent or molecular percent

7 Ion Complexes of Important Cations (with cation valence in parentheses)  SiO 2 TiO 2 (+4)  Al 2 O 3 Cr 2 O 3 Fe 2 O 3 (+3)  MgO MnO FeO CaO(+2)  Na 2 O K 2 O H 2 O (+1)

8 Problem 1 Calculate a formula for these Weight Percents  Oxide Wt% MolWt Moles Moles Moles Oxide Oxide Cation Oxygen  SiO 2 59.85 60.086.996 *.996 1.992  MgO 40.15 40.312.996.996.996  total 100% 2.998  Mole ratios Mg : Si : O = 1 : 1 : 3  Formula is: MgSiO 3 Enstatite Checked 9 Sept 2011 CLS *59.85/60.086

9 Problem 2 Formula to weight percents  Kyanite is Al 2 SiO 5  Calculate the weight percents of the oxides: – SiO 2 – Al 2 O 3

10 Problem 2 p2 Kyanite: Al 2 SiO 5  Oxide Moles MolWt Grams Wt% PFU Oxide Oxide SiO2 1 60.086 60.086 60/162 37.08 Al2O3 1 101.963 101.963 102/162 62.92 Formula weight 162.049 100% Checked 9 Sept 2011 CLS

11 Problem 3: Solid Solutions Weight percents to formula  Alkali Feldspars may exist with any composition between NaAlSi 3 O 8 ( Albite ) and KAlSi 3 O 8 ( Sanidine, Orthoclase and Microcline )  Formula has 8 oxygens: (Na,K)AlSi 3 O 8  The alkalis may substitute in any ratio, but total alkalis (Na + K) to Al is 1 to 1.

12 Problem 3 (cont’) Solid Solutions Weight percents to Formula  Oxide Wt% MolWt Moles Moles Moles Oxide Oxide Cation Oxygen  SiO2 68.20 60.086 1.1350 1.1350 2.2701  Al2O3 19.29 101.963 0.1892 0.3784.5676  Na2O 10.20 61.9796 0.1646 0.3291.1646  K2O 2.32 94.204 0.0246 0.0493.0246  100.00 3.0269  Units: Wt% [g/FU] / MolWt [g/mole]  moles\FU  3.0269 oxygens is wrong for this mineral. Multiply cations by 8.000/ 3.0269 oxygen correction  Mole ratios Na 0.87, K 0.13, Al 1.000, Si ~3.0, calculated as cations per 8 oxygens  Notice, now Na + K = 1.00, as required Checked 9 Sept 2011 CLS Answer (Na.87,K.13 )AlSi 3 O 8

13 Various Simple Solid Solutions  Alkali Feldspars  NaAlSi 3 O 8 - KAlSi 3 O 8  Orthopyroxenes:  MgSiO 3 - FeSiO 3 Enstatite - Ferrosilite (opx)  MgCaSi 2 O 6 -FeCaSi 2 O 6 Diopside-Hedenbergite (cpx)  Olivines: Mg 2 SiO 4 - Fe 2 SiO 4 Forsterite - Fayalite  Garnets:  Mg 3 Al 2 Si 3 O 12 - Fe 3 Al 2 Si 3 O 12 Pyrope - Almandine

14 Problem 4: Orthopyroxenes Solid Solution Weight Percent Oxides from Formula  Given the formula En 70 Fs 30 for an Orthopyroxene, calculate the weight percent oxides.  En = Enstatite = Mg 2 Si 2 O 6  Fs = Ferrosilite = Fe 2 Si 2 O 6  Formula is (Mg 0.7 Fe 0.3 ) 2 Si 2 O 6 = (Mg 1.4 Fe 0.6 )Si 2 O 6

15 Problem 4 Weight Percent Oxides from Formula Recall formula was (Mg 1.4 Fe 0.6 ) Si 2 O 6  Oxide Moles MolWt Grams Wt% PFU Oxide Oxide  SiO2 2 x 60.086 = 120.172 54.69  MgO 1.4 x 40.312 = 56.437 25.69  FeO 0.6 x 71.846 = 43.108 19.62  Formula weight tot. 219.717 100.00% For example 120.172/219.717 =.5469 (i.e. 54.69%) Checked 23 September 2011 CLS

16 Problem 5 Weight Percent Oxides from Formula  Consider a Pyroxene solid solution of 40% Jadeite (NaAlSi 2 O 6 ) and 60% Aegirine (NaFe +3 Si 2 O 6 ).  Calculate the weight percent oxides  Formula is Na(Al 0.4 Fe 0.6 )Si 2 O 6

17 Problem 5 continued Formula Unit is Na(Al 0.4 Fe 0.6 )Si 2 O 6 Calculate Weight Percent Oxides Oxide Moles MolWt Grams Wt% PFU Oxide Oxide  SiO 2 2.0 60.086 120.172 54.71  Al 2 O 3 0.2 101.963 20.393 9.29  Fe 2 O 3 0.3 159.692 47.908 21.83  Na 2 O 0.5 61.980 30.990 14.12  Formula weight 219.463 100.00 Example: 2x 60.086 = 120.172 120.172/219.463 =.5471 x 100 = 54.71% SiO 2 Checked Sept 9 2011 CLS Example: 0.4 moles Al given as Al 2 O 3 is 0.2 moles/per formula unit Al 2 O 3 0.2x101.963 = 20.393; 20.393/219.463 =.0929 x 100 = 9.29%

18 Some Coupled Solid Substitutions  Plagioclase Feldspar CaAl 2 Si 2 O 8 - NaAlSi 3 O 8  Jadeite - Diopside NaAlSi 2 O 6 - CaMgSi 2 O 6

19 Problem 6 Coupled Substitution  Given 40% Anorthite; 60% Albite  Calculate Weight percent Oxides First write the formulas Anorthite is CaAl 2 Si 2 O 8 Albite is NaAlSi 3 O 8 An40 Ab60 is Ca 0.4 Na 0.6 Al 1.4 Si 2.6 O 8 Notice Silica (0.4 x 2 Silica in Anorthite) + (0.6 x 3 in Albite) = 2.6 Aluminum (0.4 x 2 Aluminum in Anorthite) + (0.6 x 1 in Albite) = 1.4 Checked Sept. 9 th 2011 CLS Ca same as Anorthite, Na Same as Albite

20 Problem 6 Coupled Substitution  An40 Ab60 formula is Ca.4 Na.6 Al 1.4 Si 2.6 O 8 Oxide Moles MolWt Grams Wt% PFU Oxide Oxide SiO2 2.6 60.086 156.22 58.17 Al2O3 0.7 101.963 71.37 26.57 CaO 0.4 55.96 22.38 8.33 Na2O 0.3 61.980 18.59 6.92 Formula weight 268.58 100.00 Example: Notice Al 1.4 moles/PFU reported as Al2O3 is 0.7 PFU Checked 9 August 2007 CLS

21 Problem 7 Given Analysis Compute Mole percents Jadeite is NaAlSi2O6 Diopside is CaMgSi2O6 We are given the following chemical analysis of a Px: Oxide Wt% MolWt Moles Moles Moles Prop. Cations to O 6 Oxide Oxide Cation Oxygen  SiO 2 56.64 60.086.9426.9426 1.8852 2.00  Na 2 O 4.38 61.99.0707.1414.0707.30  Al 2 O 3 7.21 101.963.0707.1414.2121.30  MgO 13.30 40.312.3299.3299.3299.7  CaO 18.46 55.96.3299.3299.3299.7 2.8278  But pyroxenes here have 6 moles oxygens/mole, not 2.8278. Multiply moles cation by 6/2.8278  As always, Moles Oxide = weight percentage divided by molec weight  Na.3 Ca.7 Al.3 Mg.7 Si 2 O 6 = 30% Jadeite 70% Diopside This page checked Sept 2 2007 CLS  http://www.science.uwaterloo.ca/~cchieh/cact/c120/formula.html http://www.science.uwaterloo.ca/~cchieh/cact/c120/formula.html

22 Next Lecture Thermodynamics

Download ppt "Lecture 5 Crystal Chemistry Part 4: Compositional Variation of Minerals 1. Solid Solution 2. Mineral Formula Calculations."

Similar presentations

A Tour of the Rock Forming Silicates

A Tour of the Rock Forming Silicates
GOLDSCHMIDT’S RULES 1. The ions of one element can extensively replace those of another in ionic crystals if their radii differ by less than approximately.

GOLDSCHMIDT’S RULES 1. The ions of one element can extensively replace those of another in ionic crystals if their radii differ by less than approximately.
Solid Solutions A solid solution is a single phase which exists over a range in chemical compositions. Almost all minerals are able to tolerate variations.

Solid Solutions A solid solution is a single phase which exists over a range in chemical compositions. Almost all minerals are able to tolerate variations.
Back to silicate structures: nesosilicates inosilicates tectosilicates phyllosilicates cyclosilictaes sorosilicates.

Back to silicate structures: nesosilicates inosilicates tectosilicates phyllosilicates cyclosilictaes sorosilicates.
Inosilicates: single chains- pyroxenes Diopside (001) view blue = Si purple = M1 (Mg) yellow = M2 (Ca) Diopside: CaMg [Si 2 O 6 ] b a sin  Where are.

Inosilicates: single chains- pyroxenes Diopside (001) view blue = Si purple = M1 (Mg) yellow = M2 (Ca) Diopside: CaMg [Si 2 O 6 ] b a sin  Where are.
Mineral Structures Silicates are classified on the basis of Si-O polymerism the [SiO 4 ] 4- tetrahedron.

Mineral Structures Silicates are classified on the basis of Si-O polymerism the [SiO 4 ] 4- tetrahedron.
Thermobarometry Lecture 12. We now have enough thermodynamics to put it to some real use: calculating the temperatures and pressures at which mineral.

Thermobarometry Lecture 12. We now have enough thermodynamics to put it to some real use: calculating the temperatures and pressures at which mineral.
Back to silicate structures:

Back to silicate structures:
The I1−P1 and C2/c – P21/c displacive phase transitions in Ca-rich plagioclase and pigeonitic pyroxenes, respectively, produce antiphase domains (APDs)

The I1−P1 and C2/c – P21/c displacive phase transitions in Ca-rich plagioclase and pigeonitic pyroxenes, respectively, produce antiphase domains (APDs)
Lecture 4 (9/18/2006) Crystal Chemistry Part 3: Coordination of Ions Pauling’s Rules Crystal Structures.

Lecture 4 (9/18/2006) Crystal Chemistry Part 3: Coordination of Ions Pauling’s Rules Crystal Structures.
Minerals A. Changing scales to looking at the elements of the earth and its crust (8 most common) B. Introduction to minerals that comprise rocks (11 most.

Minerals A. Changing scales to looking at the elements of the earth and its crust (8 most common) B. Introduction to minerals that comprise rocks (11 most.
Average Composition of the Continental Crust Weight PercentVolume Percent Si O O Table 3.4.

Average Composition of the Continental Crust Weight PercentVolume Percent Si O O Table 3.4.
Igneous Rocks. Classification of Igneous Rocks Most Abundant Elements: O, Si, Al, Fe, Ca, Mg, K, Na Calculate Elements as Oxides (Account for O) How Much.

Igneous Rocks. Classification of Igneous Rocks Most Abundant Elements: O, Si, Al, Fe, Ca, Mg, K, Na Calculate Elements as Oxides (Account for O) How Much.
Six-sided, pyramidal Quartz Crystals.

Six-sided, pyramidal Quartz Crystals.
Mineral Chemistry and Crystallography. Definition of a Mineral All minerals: 1) Occur naturally 2) Are inorganic solids 3) Have a definitive chemical.

Mineral Chemistry and Crystallography. Definition of a Mineral All minerals: 1) Occur naturally 2) Are inorganic solids 3) Have a definitive chemical.
Pyroxene Mineral Formula

Pyroxene Mineral Formula
Phase Equilibria in Silicate Systems Intro. Petrol. EPSC-212, Francis-14.

Phase Equilibria in Silicate Systems Intro. Petrol. EPSC-212, Francis-14.
Tectosilicates: the feldspars Nesse EPSC210 Introductory Mineralogy.

Tectosilicates: the feldspars Nesse EPSC210 Introductory Mineralogy.
Ionic Coordination and Silicate Structures Lecture 4.

Ionic Coordination and Silicate Structures Lecture 4.
Mineral Structures From definition of a mineral:

Mineral Structures From definition of a mineral:

Similar presentations

Ads by Google