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Silicates:. A class of minerals based on silicon-oxygen units.

Published byRoss Parrish Modified over 7 years ago

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Presentation on theme: "Silicates:. A class of minerals based on silicon-oxygen units."— Presentation transcript:

1 Silicates:

2 A class of minerals based on silicon-oxygen units.

3 SiO 2 Si O

4 SiO 2 Si O 3-dimensional structure of SiO 4 units

5 4- Orthosilicate ion, [SiO 4 ] 4-

6 4- Orthosilicate ion, [SiO 4 ] 4- 4 -2

7 4- Orthosilicate ion, [SiO 4 ] 4- 4 -2

8 4- Orthosilicate ion, [SiO 4 ] 4- 4 -2

9 4- Orthosilicate ion, [SiO 4 ] 4- 4 -2 Forms minerals when combined with various metal counter-ions.

10 4- Orthosilicate ion, [SiO 4 ] 4- 4 -2 Forms minerals when combined with various metal counter-ions. [Mg 2+ ] 2

11 Mg 2 SiO 4 Forsterite

12 Put two tetrahedra together

13

14 Si 2 O 7 6- Disilicates

15 Si 2 O 7 6- Disilicates

16 Si 2 O 7 6- O’s above Si removed Disilicates

17 Si 2 O 7 6- O’s above Si removed Disilicates O 7 x –2 = -14 Si 2 x +4 = 8

18 Ilvaite

19

20

21 Beryl Be 3 Al 2 Si 6 O 18

22 Beryl

23

24 6 tetrahedra in ring

25 Beryl 6 tetrahedra in ring 2 shared corner/tetrahedra

26 Beryl 6 tetrahedra in ring 2 shared corner/tetrahedra each share = 1/2 O/Si

27 Beryl 6 tetrahedra in ring 2 shared corner/tetrahedra each share = 1/2 O/Si 6x2 unshared O = 12 O

28 Beryl 6 tetrahedra in ring 1 shared corner/tetrahedra each share = 1/2 O/Si 6x2 unshared O = 12 O 12 shared O = 6 O

29 Beryl 6 tetrahedra in ring 2 shared corner/tetrahedra each share = 1/2 O/Si 6x2 unshared O = 12 O 12 shared O = 6 O Si 6 O 18 Be 3 Al 2 Si 6 O 18

30 Beryl 6 tetrahedra in ring 2 shared corner/tetrahedra each share = 1/2 O/Si 6x2 unshared O = 12 O 12 shared O = 6 O Si 6 O 18 SiO 3 2-

31

32 Talc

33

34

35 6 tetrahedra

36 Each shares 3 corners

37 6 tetrahedra Each shares 3 corners Each share = 1/2 O/Si

38 6 tetrahedra Each shares 3 corners Each share = 1/2 O/Si 6x3= 18 shared

39 6 tetrahedra Each shares 3 corners Each share = 1/2 O/Si 6x3= 18 shared = 9 O

40 6 tetrahedra Each shares 3 corners Each share = 1/2 O/Si 6x3= 18 shared = 9 O 6 unshared

41 6 tetrahedra Each shares 3 corners Each share = 1/2 O/Si 6x3= 18 shared = 9 O 6 unshared Si 6 O 15

42 6 tetrahedra Each shares 3 corners Each share = 1/2 O/Si 6x3= 18 shared = 9 O 6 unshared Si 6 O 15 Si 2 O 5 2-

43 quartz

44

45

46 Tetrahedra share all corners

47 quartz Tetrahedra share all corners Each share = 1/2 O/Si

48 quartz Tetrahedra share all corners Each share = 1/2 O/Si 4/2 O/Si

49 quartz Tetrahedra share all corners Each share = 1/2 O/Si 4/2 O/Si SiO 2

50 Infinite chain

51 Each tetrahedra shares 2 corners

52 Infinite chain Each tetrahedra shares 2 corners Each Si has 2 unshared O

53 Infinite chain Each tetrahedra shares 2 corners Each Si has 2 unshared O 2 shared O = 1 O

54 Infinite chain Each tetrahedra shares 2 corners Each Si has 2 unshared O 2 shared O = 1 O 3 O/Si

55 Infinite chain Each tetrahedra shares 2 corners Each Si has 2 unshared O 2 shared O = 1 O 3 O/Si SiO 3

56 Infinite chain Each tetrahedra shares 2 corners Each Si has 2 unshared O 2 shared O = 1 O 3 O/Si SiO 3 2-

57 Infinite double chain

58

59 4 tetrahedra

60 Infinite double chain 4 tetrahedra 2 have 2 shared corners

61 Infinite double chain 4 tetrahedra 2 have 2 shared corners 2 have 3 shared corners

62 Infinite double chain 4 tetrahedra 2 have 2 shared corners 2 have 3 shared corners SiO 3

63 Infinite double chain 4 tetrahedra 2 have 2 shared corners 2 have 3 shared corners SiO 3 SiO 2.5

64 Infinite double chain 4 tetrahedra 2 have 2 shared corners 2 have 3 shared corners SiO 3 x 2 = Si 2 O 6 SiO 2.5 x 2 = Si 2 O 5

65 Infinite double chain 4 tetrahedra 2 have 2 shared corners 2 have 3 shared corners SiO 3 x 2 = Si 2 O 6 SiO 2.5 x 2 = Si 2 O 5

66 Infinite double chain 4 tetrahedra 2 have 2 shared corners 2 have 3 shared corners SiO 3 x 2 = Si 2 O 6 SiO 2.5 x 2 = Si 2 O 5 Si 4 O 11 6-

67 Mg 3 (Si 4 O 10 )(OH) 2

68 Talc

69

70 Magnesium is octahedrally coordinated to 4 Si-Os and 2 OH - s

71 Magnesium is octahedrally coordinated to 4 Si-Os and 2 OH - s Mg OH O O O O

72 Mg 3 (Si 4 O 10 )(OH) 2

73

74

75 Mg OH O O O O

76 Mg 3 (Si 4 O 10 )(OH) 2 Mg OH O O O O Weak forces

77 Graphite Structure Bonds - strong attraction van der Waal’s forces- weak attraction

78 Replace an Si with Al and add K to balance charge Mica Mg 3 (Si 4 O 10 )(OH) 2 talc

79 Replace an Si with Al and add K to balance charge Mica Mg 3 (Si 4 O 10 )(OH) 2 talc KMg 3 (AlSi 3 O 10 )(OH) 2 mica

80 Replace an Si with Al and add K to balance charge KMg 3 (AlSi 3 O 10 )(OH) 2 K Mg SiO 4 /AlO 4 units Mica

81 Replace an Si with Al and add K to balance charge KMg 3 (AlSi 3 O 10 )(OH) 2 K Mg SiO 4 /AlO 4 units Mica Mg octahedrally coordinated to six Os.

82 Mg OH O O O O Mg O O O O O O Stronger Mg – SiO 4 bonding.

83 Replace an Si with Al and add K to balance charge KMg 3 (AlSi 3 O 10 )(OH) 2 K Mg SiO 4 /AlO 4 units Mica K + O bonds are weak, leading to easy cleavage along O-layer.

84

85

86 Zeolites:

87 Another type of aluminosilicate.

88 Si/Al O M x D y (Al x+2y Si n-x-2y O n ).mH 2 O M usually K + ;D group II

89 M x D y (Al x+2y Si n-x-2y O n ).mH 2 O M usually K + ;D group II

90

91 The physical properties of the various zeolites are of more interest than their chemical properties.

92 Zeolites have openings of a variety of shapes and sizes.

93 Zeolites have openings of a variety of shapes and sizes. These openings allow zeolites to be used to absorb particular molecules and to be used as molecular sieves.

94

95 Zeolites can be used as absorbants for particular molecules.

96 Zeolites are useful for the separation of small molecules.

97 Clathrates

98 Cage-like frameworks of metals with other metals occupying the cavities of the cages.

99 Clathrates These can be synthesized by mixing finely divided quantities of the metals in the correct proportions and careful heating and cooling.

100

101

102

103

104 5 membered rings

105 5 + 6 membered rings

106

107

108

109

110 Clathrates of this type have useful thermal and semiconductor properties.

111 Clathrates of this type have useful thermal and semiconductor properties. A good semiconductor that has poor thermal conductivity is useful for making a thermo-electric device.

112 Thermo-electric cooler

113 Holes and electrons carry energy electrically.

114 Thermo-electric cooler Holes and electrons carry energy electrically. Electrical energy is converted to heat.

115 Thermo-electric cooler Holes and electrons carry energy electrically. Electrical energy is converted to heat. Poor thermal conductivity of semiconductor keeps heat from returning to cooling site.

116 Ceramics and glass

117 quartz

118 Each O bonds to 2 Si

119 quartz Each O bonds to 2 Si Each Si bonds to 4 O

120 quartz Each O bonds to 2 Si Each Si bonds to 4 O SiO 2

121 Glass Na 2 O. CaO. (SiO 2 ) 6

122 Glass Na 2 O. CaO. (SiO 2 ) 6 Approximate formula

123 Quartz: crystalline, long-range order

124 glass: short-range order but not crystalline

125 glass: short-range order but not crystalline All Si bound to 4 O

126 glass: short-range order but not crystalline All Si bound to 4 O Many O are ‘terminal’

127 glass: short-range order but not crystalline All Si bound to 4 O Many O are ‘terminal’

128 glass: short-range order but not crystalline All Si bound to 4 O Many O are ‘terminal’ Ratio of O/Si Is > 2.

129 glass: short-range order but not crystalline All Si bound to 4 O Many O are ‘terminal’ Ratio of O/Si Is > 2. Si x O y cluster is anionic

130 glass: short-range order but not crystalline Si x O y cluster is anionic Na + and Ca 2+ balance charge of anion

131 Properties of glass vs. quartz.

132 Glass has a lower melting point

133 Properties of glass vs. quartz. Glass has a lower melting point Glass is softer Glass does not crystallize – this makes it easier to shape it as it cools to a solid form.

134 Special glasses:

135 Borosilicate glass

136 Replace some of the Si sites with B

137 Borosilicate glasses have lower coefficients of expansion than soda-lime glasses.

138 Borosilicate glasses have lower coefficients of expansion than soda-lime glasses. Most materials expand when heated.

139 The coefficient of expansion is a factor, which when multiplied by the temperature change, gives the amount a material will expand or contract.

140 Since glasses are quite brittle, they are less likely to break when the temperature changes if they have a relatively low coefficient of expansion.

141 Borosilicate glasses have higher melting points than soda-lime glasses.

142 Borosilicate glasses have higher melting points than soda-lime glasses. Soda-lime glasses can be melted using a flame generated from methane and air.

143 Borosilicate glasses have higher melting points than soda-lime glasses. Soda-lime glasses can be melted using a flame generated from methane and air. It is necessary to use a methane/oxygen flame to work borosilicate glass.

144 Cements:

145 Portland cement is a specifically formulated powder.

146 Cements: Portland cement is a specifically formulated powder. When mixed with the proper amount of water it first forms a slurry which flows and can be formed.

147 When mixed with the proper amount of water it first forms a slurry which flows and can be formed. The slurry hardens and gains strength by the growth of a network of silicate crystals.

148 (CaO) 3. Al 2 O 3(s) + 3 (CaSO 4. 2 H 2 O) (s) + 26 H 2 O (CaO) 3. Al 2 O 3. (CaSO 4 ) 3. 32H 2 O (s)

149 (CaO) 3. Al 2 O 3(s) + 3 (CaSO 4. 2 H 2 O) (s) + 26 H 2 O (CaO) 3. Al 2 O 3. (CaSO 4 ) 3. 32H 2 O (s) exothermic

150 (CaO) 3. Al 2 O 3(s) + 3 (CaSO 4. 2 H 2 O) (s) + 26 H 2 O (CaO) 3. Al 2 O 3. (CaSO 4 ) 3. 32H 2 O (s) exothermic Cooling should favor the formation of products.

151 6 (CaO) 3. SiO 2(s) + 18 H 2 O (l) (CaO) 5. (SiO 2 ) 6. 5H 2 O (s) + 13 Ca(OH) 2(s)

152 6 (CaO) 3. SiO 2(s) + 18 H 2 O (l) (CaO) 5. (SiO 2 ) 6. 5H 2 O (s) + 13 Ca(OH) 2(s) crystals

153 6 (CaO) 3. SiO 2(s) + 18 H 2 O (l) (CaO) 5. (SiO 2 ) 6. 5H 2 O (s) + 13 Ca(OH) 2(s) crystals If the mixture is allowed to dry too rapidly, sufficient water and time will not be available for crystal growth.

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