1. MINERALS Introduction What Are They?
Physical Properties & Identification
Atoms & Elements
Mineral Groups

2. Minerals
Introduction

3. Eight Most Abundant Elements in Earth’s Crust
GEOL 131: Minerals - Intro
Eight Most Abundant Elements in Earth’s Crust

4. GEOL 131: Minerals - Intro

5. Some of the Most Abundant Minerals in Earth’s Crust
GEOL 131: Minerals - Intro
Some of the Most Abundant Minerals in Earth’s Crust
Quartz
Feldspars
Micas

6. Some of the Most Abundant Minerals in Earth’s Crust
GEOL 131: Minerals - Intro
Some of the Most Abundant Minerals in Earth’s Crust
Amphiboles
Pyroxenes
Olivine e

7. Minerals
Minerals
What Are They?

8. Minerals Are: Solid Naturally occurring Inorganic
GEOL 131: Minerals – What Are They?
Minerals Are:
Solid
Naturally occurring
Inorganic

9. Minerals Have: Well-defined chemical compositions
GEOL 131: Minerals – What Are They?
Minerals Have:
Well-defined chemical compositions
Well-ordered atomic structures

10. Physical Properties & Identification
Minerals
Physical Properties & Identification

11. Physical Properties Each mineral has a unique set of properties
GEOL 131: Minerals – Physical Properties & Identification
Physical Properties
Each mineral has a unique set of properties
Determined by mineral’s chemical composition and atomic structure
Properties are used to identify unknown minerals

12. Physical Properties Commonly Used in Identification
GEOL 131: Minerals – Physical Properties & Identification
Physical Properties Commonly Used in Identification
Color
Streak
Luster
Cleavage
Crystal habit
Striations
Hardness
Effervescence
Magnetism

13. COLOR Easy to observe, but can be misleading
GEOL 131: Minerals – Physical Properties & Identification
COLOR
Easy to observe, but can be misleading
Impurities can produce different colors
Quartz

14. STREAK Color of powdered mineral More reliable than “bulk” color
GEOL 131: Minerals – Physical Properties & Identification
STREAK
Color of powdered mineral
More reliable than “bulk” color
Streak plate

15. LUSTER How sample reflects light Not the same as color
GEOL 131: Minerals – Physical Properties & Identification
LUSTER
How sample reflects light
Not the same as color
NONMETALLIC luster
METALLIC luster

16. LUSTER How sample reflects light Not the same as color
GEOL 131: Minerals – Physical Properties & Identification
LUSTER
How sample reflects light
Not the same as color
Both of these minerals have a METALLIC luster

17. CLEAVAGE How sample cleaves (breaks)
GEOL 131: Minerals – Physical Properties & Identification
CLEAVAGE
How sample cleaves (breaks)
Always the same for a given mineral
Three aspects
Quality
Number of directions
Angle

18. CLEAVAGE QUALITY - None
GEOL 131: Minerals – Physical Properties & Identification
CLEAVAGE QUALITY - None
No cleavage: irregular breakage surface

19. CLEAVAGE QUALITY - Good
GEOL 131: Minerals – Physical Properties & Identification
CLEAVAGE QUALITY - Good
Note “stair-step” pattern
Good cleavage: somewhat regular breakage surface

20. CLEAVAGE QUALITY – Excellent/perfect
GEOL 131: Minerals – Physical Properties & Identification
CLEAVAGE QUALITY – Excellent/perfect
Excellent cleavage: smooth breakage surface

21. # OF CLEAVAGE DIRECTIONS
GEOL 131: Minerals – Physical Properties & Identification
# OF CLEAVAGE DIRECTIONS
A number
Only applies to good or excellent cleavage quality

22. # OF CLEAVAGE DIRECTIONS - One
GEOL 131: Minerals – Physical Properties & Identification
# OF CLEAVAGE DIRECTIONS - One
One smooth surface

23. # OF CLEAVAGE DIRECTIONS - Two
GEOL 131: Minerals – Physical Properties & Identification
# OF CLEAVAGE DIRECTIONS - Two
Two non-parallel smooth surfaces

24. # OF CLEAVAGE DIRECTIONS - Three
GEOL 131: Minerals – Physical Properties & Identification
# OF CLEAVAGE DIRECTIONS - Three
Three non-parallel smooth surfaces

25. # OF CLEAVAGE DIRECTIONS - Four
GEOL 131: Minerals – Physical Properties & Identification
# OF CLEAVAGE DIRECTIONS - Four
Fluorite
Four non-parallel smooth surfaces

26. CLEAVAGE ANGLE Angle between cleavage surfaces 60-degree angle
GEOL 131: Minerals – Physical Properties & Identification
CLEAVAGE ANGLE
Angle between cleavage surfaces
60-degree angle
90-degree angle
120-degree angle

27. CRYSTAL HABIT How a mineral grows
GEOL 131: Minerals – Physical Properties & Identification
CRYSTAL HABIT
How a mineral grows
Unusual to see well-formed crystals in nature
Need space to grow

28. CRYSTAL HABIT Well-formed crystal faces
GEOL 131: Minerals – Physical Properties & Identification
CRYSTAL HABIT
Well-formed crystal faces
Poorly-formed crystals: not enough space

29. GEOL 131: Minerals – Physical Properties & Identification
CRYSTAL HABIT
Don’t confuse a crystal face with an excellent cleavage surface
Crystal face – caused by growth
Cleavage surface – caused by breaking

30. STRIATIONS Thin grooves on mineral’s surface Can be hard to see
GEOL 131: Minerals – Physical Properties & Identification
STRIATIONS
Thin grooves on mineral’s surface
Can be hard to see
From facweb.bhc.edu
From www4.uwm.edu

31. GEOL 131: Minerals – Physical Properties & Identification
HARDNESS

32. EFFERVESCENCE If CO3 ion present, carbon dioxide bubbles will form:
GEOL 131: Minerals – Physical Properties & Identification
EFFERVESCENCE
Dilute hydrochloric acid (HCl)
If CO3 ion present,
carbon dioxide bubbles will form:
CaCO3(calcite) + 2HCl =
H2O + CO2 + CaCl2

33. Magnetite (Fe3O4) attracting a magnet
GEOL 131: Minerals – Physical Properties & Identification
MAGNETISM
Some iron-rich minerals are magnetic
Magnetite (Fe3O4) attracting a magnet

34. MINERAL IDENTIFICATION
GEOL 131: Minerals – Physical Properties & Identification
MINERAL IDENTIFICATION
Table or flowchart
Observation of unique properties
Narrow down possibilities

35. MINERAL IDENTIFICATION
GEOL 131: Minerals – Physical Properties & Identification
MINERAL IDENTIFICATION

36. Minerals
Atoms & Elements

37. All Minerals Are Made of Atoms
GEOL 131: Minerals – Atoms and Elements
All Minerals Are Made of Atoms

38. GEOL 131: Minerals – Atoms and Elements The Periodic Table of the Elements

39. Basic Structure of an Atom
GEOL 131: Minerals – Atoms and Elements
Basic Structure of an Atom

40. GEOL 131: Minerals – Atoms and Elements
Valence Shells

41. Atomic Bonds Hold atoms together to make mineral crystals
GEOL 131: Minerals – Atoms and Elements
Atomic Bonds
Hold atoms together to make mineral crystals
Formed by electron interaction
Require filled valence shells

42. GEOL 131: Minerals – Atoms and Elements
Atomic Bonds

43. GEOL 131: Minerals – Atoms and Elements
Atomic Bonds

44. Chemical Composition of Minerals
GEOL 131: Minerals – Atoms and Elements
Chemical Composition of Minerals
Elements present and in what amounts
Well-defined: Limited or no variation
Described by mineral’s formula
Halite (salt): NaCl

45. Atomic Structure of Minerals
GEOL 131: Minerals – Atoms and Elements
Atomic Structure of Minerals
Arrangement of atoms
Well-ordered: Repeats in a regular pattern

46. Atomic Structure of Minerals
GEOL 131: Minerals – Atoms and Elements
Atomic Structure of Minerals
Arrangement of atoms
QUARTZ

47. Atomic Structure – Diamond vs Graphite
GEOL 131: Minerals – Atoms and Elements
Atomic Structure – Diamond vs Graphite

48. MINERAL GROUPS Silicates (largest group) Carbonates Sulfates Sulfides
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS
Silicates (largest group)
Carbonates
Sulfates
Sulfides
Oxides
Halides
Native elements

49. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Largest group
90% of Earth’s crust
Si and O atoms in a tetrahedron (pyramid)

50. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Oxygen atoms can bond to adjacent tetrahedra in a mineral’s atomic structure
Forms the “backbone” of the mineral
Example: single-chain structure
Each tetrahedron shares two oxygens with adjacent tetrahedra

51. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Silicate structures

52. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
A silicate mineral’s properties depend partly on its silicate structure
Hardness: 3-D networks make harder minerals (quartz)
Cleavage: sheet structures produce sheet cleavage (micas)

53. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Example: Hardness
3-D frameworks make harder minerals
Quartz

54. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Example: Cleavage
Sheet structures produce sheet cleavage
Micas

55. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Dark vs. light silicates
Dark: rich in Fe and Mg
Light: little Fe or Mg
Important for igneous rocks (next chapter)

56. MINERAL GROUPS - Silicates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS - Silicates
Some common silicate minerals
Quartz: SiO2
Orthoclase feldspar (aka potassium feldspar or K-spar): KAlSi3O8
Muscovite mica: KAl2(AlSi3O10)(F,OH)2
Hornblende: Ca2(Mg, Fe, Al)5 (Al, Si)8O22(OH)2

57. MINERAL GROUPS – Carbonates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS – Carbonates
CO3 ion
Effervescence
Common examples
Calcite: CaCO3
Dolomite: CaMg(CO3)2
Malachite: Cu2CO3(OH)2
Malachite

58. MINERAL GROUPS – Sulfates
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS – Sulfates
SO4 ion
Common examples
Gypsum: CaMgSO4*2H2O
Anhydrite: CaMgSO4
Barite: BaSO4
Giant gypsum crystals, Naica Mine, Mexico

59. MINERAL GROUPS – Sulfides
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS – Sulfides
S, no oxygen
Important metal ores
Common examples
Galena: PbS
Pyrite: FeS
Chalcopyrite: CuFeS2
Cubic galena crystals

60. MINERAL GROUPS – Oxides
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS – Oxides
Oxygen
No Si, C, or S
Common examples
Hematite: Fe2O3
Magnetite: Fe3O4
Corundum: Al2O3
Red corundum (ruby)

61. MINERAL GROUPS – Halides
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS – Halides
Cl, F, or Br
Common examples
Halite (salt): NaCl
Fluorite: CaF2
Wieliczka salt mine, Poland

62. MINERAL GROUPS – Native elements
GEOL 131: Minerals – Mineral Groups
MINERAL GROUPS – Native elements
Any element in pure form
Common examples
Sulfur (S)
Graphite (C)
Copper (Cu)

63. End of Minerals chapter