1. Structure of the Silicate Minerals Comparing Crystal Structures to Visible Mineral Properties

2. Silicon, Silicates, Silicones How to Tell the Difference Silicon: One of 92 naturally occurring chemical elements

3. Silicon, Silicates, Silicones How to Tell the Difference Silicon (cont.): Silicon is a metalloid: Its nucleus is comprised of: 14 protons 14 neutrons surrounded by: 14 electrons.

4. Silicon

5. Silicon, Silicates, Silicones How to Tell the Difference Silicon Wafer

6. Silicon structure

7. Silicon, Silicates, Silicones How to Tell the Difference Silicates : Atoms join together to make molecules. Each silicate mineral is made of molecules. 90 % of Earth’s rocks are made of silicate minerals.

8. Silicon, Silicates, Silicones How to Tell the Difference Sand Grains SiO 2

9. Silica GeL Silica Gel is man-made. It is used to soak up moisture.

10. Silicates

11. Metallic Silicon + Oxygen Gas combine to make…

12. Silicates …glassy silicate gemstones.

13. Silicate Tetrahedron Silicates are classified on the basis of the arrangement of their silicate tetrahedra: The culprit: the [SiO 4 ] 4- tetrahedron Silicon Oxygen

14. Silicon, Silicates, Silicones How to Tell the Difference Silicones: long, rubbery molecules quite different from silicates not like minerals at all.

15. Silicon, Silicates, Silicones How to Tell the Difference Silicones (cont.): – Si – O – Si – O – Si – O backbone carbon-based (organic) molecular groups attached to the silicon atoms.

16. Silicones Silicones: Used for: Silicone caulk Silicone cement or glue

17. Silicones Silicones: Used for: Lubrication and Waterproof coatings

18. Silicones Silicones: Used to simulate flesh in cosmetic surgery (facial reconstruction and breast implants).

19. Silicones Silicones: Used to simulate flesh in cosmetic surgery (facial reconstruction and breast implants).

20. Structure of the Silicate Minerals Comparing Crystal Structures to Visible Mineral Properties

21. I. Independent Tetrahedra Structure: Tetrahedra are not directly linked together. Oxygen “corners” of tetrahedra are linked by metallic ions such as iron (Fe).

22. I. Independent Tetrahedra Structure:

23. As a result, olivine is often granular and crumbly. Ex: Olivine, Kyanite, Garnets, Topaz

24. Other Independent Tetrahedra Minerals Kyanite

25. Garnet

26. Topaz / Staurolite

27. II.Chain Structure: Chains can be single chain or double chain. In single chain silicates, each tetrahedra shares two of its four oxygen “corners” with two other tetrahedra.

28. II.Chain Structure: Chains can be single chain or double chain. Test Question: How many oxygen atoms is Silicon atom X sharing with its neighbors?

29. II.Chain Structure: In a double chain silicate, a third oxygen “corner” is shared between tetrahedra from two parallel chains.

30. II.Chain Structure: Chains of tetrahedra are held together by linking metallic ions: Linking bonds are much weaker than the Si–O bonds of the tetrahedra, causes chain silicates to have a stringy or fibrous texture.

31. Inosilicates: single chain- pyroxenes = Layers of purple Mg and yellow Ca ions create weak bonds and cleavage planes = Layers of purple Mg and yellow Ca ions create weak bonds and cleavage planes

32. II.Chain Structure: Actinolite is a good example of a fibrous chain silicate.

33. II.Chain Structure: Hornblende and Augite are common Chain Structure minerals.

34. Inosilicates: single chain STRUCTURE - pyroxenes – Pectolite & Wollastonite Typical stringy, fibrous chain silicates

35. Inosilicates: single chain- pyroxenes – Kunzite A chain silicate gemstone

36. Inosilicates - Double Chain Structure Test Question: How many oxygen atoms is Silicon atom X sharing with its neighbors now?

37. Inosilicates - Double Chain Structure – Actinolite & Tremolite Typical stringy, fibrous chain silicates

38. Cyclosilicates – Ring Structure

39. Two oxygen “corners” are shared with other silicate tetrahedra. The tetrahedra joined in rings of 3, 4, or 6 tetrahedra. Ring structures are not common. Ring structure - usually long barrel- shaped crystals (hexagonal prisms). Cyclosilicates – Ring Structure

40. Cyclosilicates – Ring Structure - Emerald

41. Cyclosilicates: Ring Structure Aquamarine

42. Cyclosilicates – Ring Structure Red Beryl

43. Cyclosilicates – Ring Structure Tourmaline

44. Every tetrahedra shares all three of its base “corners” with three neighboring tetrahedra to form continuous flat sheets of tetrahedra. IV.Sheet Structure:

45. Six tetrahedra form a basic hexagonal shape which is repeated over and over. IV.Sheet Structure:

46. How many of its 4 oxygen atoms is Silicon atom Z sharing with its neighbor Silicons?

47. Fourth oxygen “corner” of each tetrahedra is pointing either up or down. (See Side View on next slide.) IV.Sheet Structure:

48. Fourth corners are linked to layers of metals (K, Al, Fe, Mg) Metals are linked to the “corners” sticking out of the next sheet of tetrahedra. Looks like a silicate / metal “sandwich”. IV.Sheet Structure: SiO 2 Sheet Metal Layer

49. Metallic linking bonds: are much weaker than the Si – O bonds within each sheet, so they break easily. IV.Sheet Structure:

50. Muscovite and Biotite Mica: Are sheet silicates Split easily into paper-thin sheets Have perfect one direction cleavage. IV.Sheet Structure:

51. Phyllosilicates - Sheet Structure Muscovite Mica

52. Phyllosilicates - Sheet Structure Biotite Mica

53. Phyllosilicates - Sheet Structure LEPIDOLITE Mica

54. Phyllosilicates - Sheet Structure Chrysacolla Chrysacolla is a sheet silicate, but it is made of microscopic flat flakes.

55. Phyllosilicates - Sheet Structure Chrysacolla Kaolinite (clay) is a sheet silicate, but it is made of microscopic flat flakes.

56. Phyllosilicates - Sheet Structure Talc Talc is made of small, flat flakes that slide over each other easily – causes talc’s “soapy” feel.

57. Phyllosilicates - Sheet Structure Talc

58. 3-Dimensional Framework Si Tetrahedra shares all four “corners” with its four neighboring tetrahedra … W

59. 3-Dimensional Framework …to form a continuous 3-dimensional network or framework.

60. 3-Dimensional Framework

61. Bonds are equally strong in all directions. Produce minerals that are exceptionally hard.

62. 3-Dimensional Framework Bonds are equally strong in all directions: Minerals do not break with cleavage no layers of weak bonds to give way. Rose QuartzMilky Quartz

63. 3-Dimensional Framework Structure - Quartz

64. Rock Crystal Quartz

65. 3-Dimensional Framework Structure - Quartz CitrineRose Quartz

66. 3-Dimensional Framework Structure - Quartz Jasper Chert

67. modified Framework Some of the silicon ions are replaced by metal ions (K, Al, Na, and Ca). Na FeldsparK Feldspar

68. modified Framework Start with a regular framework mineral (Milky Quartz): SiO 2 Milky Quartz

69. modified Framework Keep the Si:O ratio at 1:2 and it’s still quartz. Si 2 O 4 Milky Quartz

70. modified Framework Si 4 O 8 Milky Quartz Keep the Si:O ratio at 1:2 and it’s still quartz.

71. modified Framework Remove one of the Silicons (Si 4+ )… K Feldspar Si 4 O 8

72. modified Framework Remove one of the Silicons (Si 4+ )… K Feldspar Si 3 O 8

73. modified Framework …and replace it with an Aluminum ion (Al 3+ ) AlSi 3 O 8 K Feldspar

74. modified Framework Still need another +1 metal ion to balance out the charges ( K + or Na + ) KAlSi 3 O 8 K Feldspar Et voilà– le’ Framework Modifiée!! (Modified Framework Structure)

75. 3-Dimensional Framework Layers of metal ions create layers of weak bonds Modified Framework minerals do have cleavage planes. Na Feldspar K Feldspar

76. 3-Dimensional Framework Structure - Feldspars Amazonite Feldspar

77. 3-Dimensional Framework Structure - Feldspars Labradorite Feldspar Albite Feldspar

78. 3-Dimensional Framework Structure – Sodalite

79. Many visible physical properties of minerals are reflections of their atomic structure:SUMMARY

80. The scaly micas split along parallel cleavage planes due to their sheet structure :SUMMARY

81. Some amphiboles such as actinolite are fibrous (stringy) due to their chain structure.SUMMARY

82. Olivine weathers easily because the iron atoms that link its independent tetrahedra rust out, causing the tetrahedra to fall apart.SUMMARY

83. Quartz is hard and shows no cleavage because its tetrahedra form a 3 – Dimensional Framework which is equally strong in all directions.SUMMARY

84. The explanation for all of a mineral’s properties can be found among its atoms.SUMMARY