1. Chapter 10 Liquids and Solids

2. Copyright © Cengage Learning. All rights reserved 2 Intramolecular Bonding “Within” the molecule. Molecules are formed by sharing electrons between the atoms.

3. Intermolecular Forces Intermolecular forces are attractive forces between molecules. Intramolecular forces hold atoms together in a molecule. Intermolecular vs Intramolecular 41 kJ to vaporize 1 mole of water (inter) 930 kJ to break all O-H bonds in 1 mole of water (intra) Generally, intermolecular forces are much weaker than intramolecular forces. “Measure” of intermolecular force boiling point melting point  H vap  H fus  H sub

4. Intermolecular Forces; Explaining Liquid Properties The term van der Waals forces is a general term including dipole-dipole and London forces. Van der Waals forces are the weak attractive forces in a large number of substances. Hydrogen bonding occurs in substances containing hydrogen atoms bonded to certain very electronegative atoms.

5. Van der Waals Forces 7 Van der Waals Forces are types of intermolecular forces. Consists of: 1Dipole-dipole interactions 2 Ion-dipole interactions 3 London forces

6. Dipole-Dipole Forces Polar molecules can attract one another through dipole-dipole forces. The dipole-dipole force is an attractive intermolecular force resulting from the tendency of polar molecules to align themselves positive end to negative end. H Cl   H  

7. Intermolecular Forces Dipole-Dipole Forces Attractive forces between polar molecules Orientation of Polar Molecules in a Solid

8. Intermolecular Forces Ion-Dipole Forces Attractive forces between an ion and a polar molecule Ion-Dipole Interaction

10. London Forces London forces are the weak attractive forces resulting from instantaneous dipoles that occur due to the distortion of the electron cloud surrounding a molecule. London forces increase with molecular weight. The larger a molecule, the more easily it can be distorted to give an instantaneous dipole. All covalent molecules exhibit some London force.

11. London forces: –exist between all molecules, –is the only attractive force between nonpolar atoms or molecules, –and dipole-dipole attractions occur between polar molecules. Electrons are in constant motion. Electrons can be, in an instant, arranged in such a way that they have a dipole. (Instantaneous dipole) The temporary dipole interacts with other temporary dipoles to cause attraction.

12. Intermolecular Forces Dispersion Forces Attractive forces that arise as a result of temporary dipoles induced in atoms or molecules ion-induced dipole interaction dipole-induced dipole interaction

13. Induced Dipoles Interacting With Each Other

14. Intermolecular Forces Dispersion Forces Continued Polarizability is the ease with which the electron distribution in the atom or molecule can be distorted. Polarizability increases with: greater number of electrons more diffuse electron cloud Dispersion forces usually increase with molar mass.

15. S O O What type(s) of intermolecular forces exist between each of the following molecules? HBr HBr is a polar molecule: dipole-dipole forces. There are also dispersion forces between HBr molecules. CH 4 CH 4 is nonpolar: dispersion forces. SO 2 SO 2 is a polar molecule: dipole-dipole forces. There are also dispersion forces between SO 2 molecules.

16. Hydrogen Bonding Hydrogen bonding is a force that exists between a hydrogen atom covalently bonded to a very electronegative atom, X, and a lone pair of electrons on a very electronegative atom, Y. To exhibit hydrogen bonding, one of the following three structures must be present. H NOHFH ::: Only N, O, and F are electronegative enough to leave the hydrogen nucleus exposed.

17. Hydrogen Bonding Hydrogen bonding: –not considered a Van der Waals Force –is a special type of dipole-dipole attraction –is a very strong intermolecular attraction causing higher than expected b.p. and m.p. Requirement for hydrogen bonding: –molecules have hydrogen directly bonded to O, N, or F

18. Examples of hydrogen bonding: H 2 O NH 3 HF

19. Intermolecular Forces Hydrogen Bond The hydrogen bond is a special dipole-dipole interaction between they hydrogen atom in a polar N-H, O-H, or F-H bond and an electronegative O, N, or F atom. A H … B A H … A or A & B are N, O, or F

20. Hydrogen Bond

21. Hydrogen Bonding Molecules exhibiting hydrogen bonding have abnormally high boiling points compared to molecules with similar van der Waals forces. For example, water has the highest boiling point of the Group VI hydrides. Similar trends are seen in the Group V and VII hydrides.

22. Why is the hydrogen bond considered a “special” dipole-dipole interaction? Decreasing molar mass Decreasing boiling point

23. Review: Hydrogen Bonding A hydrogen atom bonded to an electronegative atom appears to be special. The electrons in the O-H bond are drawn to the O atom, leaving the dense positive charge of the hydrogen nucleus exposed. It’s the strong attraction of this exposed nucleus for the lone pair on an adjacent molecule that accounts for the strong attraction. A similar mechanism explains the attractions in HF and NH 3.

24. Review: Hydrogen Bonding H H O : : H H O : : H H O : : H H O : :

25. Copyright © Cengage Learning. All rights reserved 25 Which are stronger, intramolecular bonds or intermolecular forces? How do you know? CONCEPT CHECK!

26. Copyright © Cengage Learning. All rights reserved 26 Phase Changes When a substance changes from solid to liquid to gas, the molecules remain intact. The changes in state are due to changes in the forces among molecules rather than in those within the molecules.

27. Copyright © Cengage Learning. All rights reserved 27 Schematic Representations of the Three States of Matter

28. Copyright © Cengage Learning. All rights reserved 28 Phase Changes Solid to Liquid –As energy is added, the motions of the molecules increase, and they eventually achieve the greater movement and disorder characteristic of a liquid. Liquid to Gas –As more energy is added, the gaseous state is eventually reached, with the individual molecules far apart and interacting relatively little.

29. A phase is a homogeneous part of the system in contact with other parts of the system but separated from them by a well-defined boundary. 2 Phases Solid phase - ice Liquid phase - water

30. Copyright © Cengage Learning. All rights reserved 30 Densities of the Three States of Water

31. Copyright © Cengage Learning. All rights reserved 31 Which molecule is capable of forming stronger intermolecular forces? N 2 H 2 O Explain. CONCEPT CHECK!

32. Copyright © Cengage Learning. All rights reserved 32 Draw two Lewis structures for the formula C 2 H 6 O and compare the boiling points of the two molecules. CONCEPT CHECK!

33. Copyright © Cengage Learning. All rights reserved 33 Which gas would behave more ideally at the same conditions of P and T? CO or N 2 Why? CONCEPT CHECK!

34. Liquids Low compressibility, lack of rigidity, and high density compared with gases. Surface tension – resistance of a liquid to an increase in its surface area: –Liquids with large intermolecular forces tend to have high surface tensions. Copyright © Cengage Learning. All rights reserved 34

35. Properties of Liquids Surface tension is the amount of energy required to stretch or increase the surface of a liquid by a unit area. Strong intermolecular forces High surface tension A molecule within a liquid is pulled in all directions, whereas a molecule on the surface is only pulled to the interior. As a result, there is a tendency for the surface area of the liquid to be minimized.

36. Surface tension - a measure of the attractive forces exerted among molecules at the surface of a liquid. Surface molecules are surrounded and attracted by fewer liquid molecules than those below. Net attractive forces on surface molecules pull them downward. –Results in “beading” Surfactant - substance added which decreases the surface tension –example: soap Review: Surface Tension

37. Surfactant - substance added which decreases the surface tension The nonpolar end is hydrophobic. The polar end is hydrophilic. Surfactants are amphipathic. Example - soap

39. DDBSA is the largest-volume synthetic surfactant because of its relatively low cost, good performance, the fact that it can be dried to a stable powder. DDBSA is also bio-degradable, thus providing environmental friendliness. DDBSA is mainly used to produce household detergents including laundry powders, laundry detergents, dishwashing liquids and other household cleaners. It is used as an emulsifier for applications like agricultural produces and industrial lubricants (Calcium Sulfonate Grease).

40. DDBSA as a detergent in water: The Sinking Duck!!!!!!!

41. Why? At the air-water interface the hydrophobic end can escape the water, whereas the hydrophilic end remains nestled in the water’s surface. The concentration of water at the interface is reduced. Therefore, the attractive forces between molecules at the interface is reduced, thus the surface tension is reduced.

42. Liquids Capillary action – spontaneous rising of a liquid in a narrow tube: –Cohesive forces – intermolecular forces among the molecules of the liquid. –Adhesive forces – forces between the liquid molecules and their container. Copyright © Cengage Learning. All rights reserved 42

43. Properties of Liquids Cohesion is the intermolecular attraction between like molecules Adhesion is an attraction between unlike molecules Adhesion Cohesion

44. Which force dominates alongside the glass tube – cohesive or adhesive forces? cohesive forces Convex Meniscus Formed by Nonpolar Liquid Mercury Copyright © Cengage Learning. All rights reserved 44

45. Concave Meniscus Formed by Polar Water Which force dominates alongside the glass tube – cohesive or adhesive forces? adhesive forces Copyright © Cengage Learning. All rights reserved 45

46. Van der Waals Forces and the Properties of Liquids Viscosity increases with increasing intermolecular forces because increasing these forces increases the resistance to flow. Other factors, such as the possibility of molecules tangling together, affect viscosity. Liquids with long molecules that tangle together are expected to have high viscosities.

47. Intermolecular Forces; Explaining Liquid Properties Viscosity is the resistance to flow exhibited by all liquids and gases. Viscosity can be illustrated by measuring the time required for a steel ball to fall through a column of the liquid. Even without such measurements, you know that syrup has a greater viscosity than water. In comparisons of substances, as intermolecular forces increase, viscosity usually increases.

49. Properties of Liquids Viscosity is a measure of a fluid’s resistance to flow. Strong intermolecular forces High viscosity

50. Kinetic Viscometery

51. Viscometers

52. Solids Amorphous Solids: –Disorder in the structures –Glass Crystalline Solids: –Ordered Structures –Unit Cells Copyright © Cengage Learning. All rights reserved 52

53. Solid State A solid is a nearly incompressible state of matter with a well-defined shape. The units making up the solid are in close contact and in fixed positions. Solids are characterized by the type of force holding the structural units together. In some cases, these forces are intermolecular, but in others they are chemical bonds (metallic, ionic, or covalent).

54. A crystalline solid possesses rigid and long-range order. In a crystalline solid, atoms, molecules or ions occupy specific (predictable) positions. An amorphous solid does not possess a well-defined arrangement and long-range molecular order. A unit cell is the basic repeating structural unit of a crystalline solid. Unit Cell lattice point Unit cells in 3 dimensions At lattice points: Atoms Molecules Ions

59. Shared by 8 unit cells Shared by 2 unit cells

60. 1 atom/unit cell (8 x 1/8 = 1) 2 atoms/unit cell (8 x 1/8 + 1 = 2) 4 atoms/unit cell (8 x 1/8 + 6 x 1/2 = 4)

62. When silver crystallizes, it forms face-centered cubic cells. The unit cell edge length is 409 pm. Calculate the density of silver. d = m V V = a 3 = (409 pm) 3 = 6.83 x 10 -23 cm 3 4 atoms/unit cell in a face-centered cubic cell m = 4 Ag atoms 107.9 g mole Ag x 1 mole Ag 6.022 x 10 23 atoms x = 7.17 x 10 -22 g d = m V 7.17 x 10 -22 g 6.83 x 10 -23 cm 3 = = 10.5 g/cm 3

63. Crystal Defects There are principally two kinds of defects that occur in crystalline substances. Chemical impurities, such as in rubies, where the crystal is mainly aluminum oxide with an occasional Al 3+ ion replaced with Cr 3+, which gives a red color. Defects in the formation of the lattice. Crystal planes may be misaligned, or sites in the crystal lattice may remain vacant.

65. Bragg Equation  Used to determine the interatomic spacings. n = integer = wavelength of the X rays d = distance between the atoms = angle of incidence and reflection Copyright © Cengage Learning. All rights reserved 65

66. Extra distance = BC + CD = 2d sin  = n (Bragg Equation)

67. X rays of wavelength 0.154 nm are diffracted from a crystal at an angle of 14.17 0. Assuming that n = 1, what is the distance (in pm) between layers in the crystal? n = 2d sin  n = 1  = 14.17 0 = 0.154 nm = 154 pm d = n 2sin  = 1 x 154 pm 2 x sin14.17 = 314.0 pm

68. Types of Crystalline Solids Ionic Solids – ions at the points of the lattice that describes the structure of the solid. Molecular Solids – discrete covalently bonded molecules at each of its lattice points. Atomic Solids – atoms at the lattice points that describe the structure of the solid. Copyright © Cengage Learning. All rights reserved 68

69. Examples of Three Types of Crystalline Solids Copyright © Cengage Learning. All rights reserved 69

70. Classification of Solids Copyright © Cengage Learning. All rights reserved 70

71. Closest Packing Model Closest Packing: –Assumes that metal atoms are uniform, hard spheres. –Spheres are packed in layers. Copyright © Cengage Learning. All rights reserved 71

72. The Closest Packing Arrangement of Uniform Spheres abab packing – the 2 nd layer is like the 1 st but it is displaced so that each sphere in the 2 nd layer occupies a dimple in the 1 st layer. The spheres in the 3 rd layer occupy dimples in the 2 nd layer so that the spheres in the 3 rd layer lie directly over those in the 1 st layer. Copyright © Cengage Learning. All rights reserved 72

73. The Closest Packing Arrangement of Uniform Spheres abca packing – the spheres in the 3 rd layer occupy dimples in the 2 nd layer so that no spheres in the 3 rd layer lie above any in the 1 st layer. The 4 th layer is like the 1 st. Copyright © Cengage Learning. All rights reserved 73

74. Hexagonal Closest Packing Copyright © Cengage Learning. All rights reserved 74

75. Cubic Closest Packing Copyright © Cengage Learning. All rights reserved 75

76. The Indicated Sphere Has 12 Nearest Neighbors Each sphere in both ccp and hcp has 12 equivalent nearest neighbors. Copyright © Cengage Learning. All rights reserved 76

77. The Net Number of Spheres in a Face-Centered Cubic Unit Cell Copyright © Cengage Learning. All rights reserved 77

78. Determine the number of metal atoms in a unit cell if the packing is: a)Simple cubic b)Cubic closest packing a)1 metal atom b)4 metal atoms Copyright © Cengage Learning. All rights reserved 78 CONCEPT CHECK!

79. A metal crystallizes in a face-centered cubic structure. Determine the relationship between the radius of the metal atom and the length of an edge of the unit cell. Copyright © Cengage Learning. All rights reserved 79 CONCEPT CHECK!

80. Silver metal crystallizes in a cubic closest packed structure. The face centered cubic unit cell edge is 409 pm. Calculate the density of the silver metal. Density = 10.5 g/cm 3 Copyright © Cengage Learning. All rights reserved 80 CONCEPT CHECK!

81. Bonding Models for Metals Electron Sea Model Band Model (MO Model) Copyright © Cengage Learning. All rights reserved 81

82. The Electron Sea Model A regular array of cations in a “sea” of mobile valence electrons.

83. Types of Crystals Metallic Crystals Lattice points occupied by metal atoms Held together by metallic bonds Soft to hard, low to high melting point Good conductors of heat and electricity Iron, copper, and silver Cross Section of a Metallic Crystal nucleus & inner shell e - mobile “sea” of e -

84. Band or Molecular Orbital (MO) Model Electrons are assumed to travel around the metal crystal in molecular orbitals formed from the valence atomic orbitals of the metal atoms. Copyright © Cengage Learning. All rights reserved 84

85. Molecular Orbital Energy Levels Produced When Various Numbers of Atomic Orbitals Interact Copyright © Cengage Learning. All rights reserved 85

86. The Band Model for Magnesium Virtual continuum of levels, called bands. Copyright © Cengage Learning. All rights reserved 86

87. Metal Alloys Substitutional Alloy – some of the host metal atoms are replaced by other metal atoms of similar size. Interstitial Alloy – some of the holes in the closest packed metal structure are occupied by small atoms. Copyright © Cengage Learning. All rights reserved 87

88. Two Types of Alloys Brass is a substitutional alloy. Steel is an interstitial alloy. Copyright © Cengage Learning. All rights reserved 88

89. Network Solids Copyright © Cengage Learning. All rights reserved 89 To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

90. Types of Crystals diamond graphite carbon atoms Covalent Crystals Lattice points occupied by atoms Held together by covalent bonds Hard, high melting point, boiling point Poor conductor of heat and electricity Extremely Hard Diamond

91. Partial Representation of the Molecular Orbital Energies in a) Diamond b) a Typical Metal Copyright © Cengage Learning. All rights reserved 91

92. The p Orbitals and Pi-system in Graphite Copyright © Cengage Learning. All rights reserved 92

93. Ceramics Typically made from clays (which contain silicates) and hardened by firing at high temperatures. Nonmetallic materials that are strong, brittle, and resistant to heat and attack by chemicals. Copyright © Cengage Learning. All rights reserved 93

94. Semiconductors n-type semiconductor – substance whose conductivity is increased by doping it with atoms having more valence electrons than the atoms in the host crystal. p-type semiconductor – substance whose conductivity is increased by doping it with atoms having fewer valence electrons than the atoms of the host crystal. Copyright © Cengage Learning. All rights reserved 94

95. Energy Level Diagrams for (a) an n-type Semiconductor (b) a p-type Semiconductor Copyright © Cengage Learning. All rights reserved 95

96. Silicon Crystal Doped with (a) Arsenic and (b) Boron

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98. Copyright © Cengage Learning. All rights reserved 98 To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

99. Ionic Solids Ionic solids are stable, high melting substances held together by the strong electrostatic forces that exist between oppositely charged ions. Copyright © Cengage Learning. All rights reserved 99

100. Types of Crystals Ionic Crystals Lattice points occupied by cations and anions Held together by electrostatic attraction Hard, brittle, high melting point, boiling point Poor conductor of heat and electricity If dissolves in water, electrolytes NaCl CsClZnSCaF 2

101. Three Types of Holes in Closest Packed Structures 1)Trigonal holes are formed by three spheres in the same layer. Copyright © Cengage Learning. All rights reserved 101

102. Three Types of Holes in Closest Packed Structures 2)Tetrahedral holes are formed when a sphere sits in the dimple of three spheres in an adjacent layer. Copyright © Cengage Learning. All rights reserved 102

103. Three Types of Holes in Closest Packed Structures 3)Octahedral holes are formed between two sets of three spheres in adjoining layers of the closest packed structures. Copyright © Cengage Learning. All rights reserved 103

104. For spheres of a given diameter, the holes increase in size in the order: trigonal < tetrahedral < octahedral Copyright © Cengage Learning. All rights reserved 104

105. Types and Properties of Solids Copyright © Cengage Learning. All rights reserved 105

106. Vapor Pressure Liquids are continuously vaporizing. If a liquid is in a closed vessel with space above it, a partial pressure of the vapor state builds up in this space. The vapor pressure of a liquid is the partial pressure of the vapor over the liquid, measured at equilibrium at a given temperature.

107. Vapor Pressure The vapor pressure of a liquid depends on its temperature. As the temperature increases, the kinetic energy of the molecular motion becomes greater, and vapor pressure increases. Liquids and solids with relatively high vapor pressures at normal temperatures are said to be volatile.

108. Behavior of a Liquid in a Closed Container a) Initially b) at Equilibrium Copyright © Cengage Learning. All rights reserved 108

109. Vapor Pressure of a Liquid 6 What happens when you put water in a sealed container? Both liquid water and water vapor will exist in the container. How does this happen below the boiling point? Kinetic Theory - Liquid molecules are in continuous motion, with their average kinetic energy directly proportional to the Kelvin temperature.

110. The equilibrium vapor pressure is the vapor pressure measured when a dynamic equilibrium exists between condensation and evaporation H 2 O (l) H 2 O (g) Rate of condensation Rate of evaporation = Dynamic Equilibrium

111. The Rates of Condensation and Evaporation Copyright © Cengage Learning. All rights reserved 111

112. Vapor Pressure Pressure of the vapor present at equilibrium. The system is at equilibrium when no net change occurs in the amount of liquid or vapor because the two opposite processes exactly balance each other. Copyright © Cengage Learning. All rights reserved 112

113. What is the vapor pressure of water at 100°C? How do you know? 1 atm Copyright © Cengage Learning. All rights reserved 113

114. Vapor Pressure Copyright © Cengage Learning. All rights reserved 114

115. Vapor Pressure Liquids in which the intermolecular forces are large have relatively low vapor pressures. Vapor pressure increases significantly with temperature. Copyright © Cengage Learning. All rights reserved 115

116. Vapor Pressure vs. Temperature Copyright © Cengage Learning. All rights reserved 116

117. Clausius–Clapeyron Equation P vap = vapor pressure ΔH vap = enthalpy of vaporization R = 8.3145 J/K·mol T = temperature (in kelvin) Copyright © Cengage Learning. All rights reserved 117

118. A Problem to Consider Carbon disulfide, CS 2, has a normal boiling point of 46 o C (vapor pressure = 760 mmHg) and a heat of vaporization of 26.8 kJ/mol. What is the vapor pressure of carbon disulfide at 35 o C? Taking the antiln we obtain:

119. The vapor pressure of water at 25°C is 23.8 torr, and the heat of vaporization of water at 25°C is 43.9 kJ/mol. Calculate the vapor pressure of water at 65°C. 194 torr Copyright © Cengage Learning. All rights reserved 119

120. Changes of State Copyright © Cengage Learning. All rights reserved 120 To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

121. Heating Curve for Water Copyright © Cengage Learning. All rights reserved 121

122. Which would you predict should be larger for a given substance: ΔH vap or ΔH fus ? Explain why. Copyright © Cengage Learning. All rights reserved 122 CONCEPT CHECK!

123. A convenient way of representing the phases of a substance as a function of temperature and pressure: –Triple point –Critical point –Phase equilibrium lines Copyright © Cengage Learning. All rights reserved 123

124. Phase Diagrams A phase diagram is a graphical way to summarize the conditions under which the different states of a substance are stable. The diagram is divided into three areas representing each state of the substance. The curves separating each area represent the boundaries of phase changes.

125. Phase Diagrams Below is a typical phase diagram. It consists of three curves that divide the diagram into regions labeled “solid, liquid, and gas”. B temperature pressure A C D solidliquid gas..

126. Phase Diagrams Curve AB, dividing the solid region from the liquid region, represents the conditions under which the solid and liquid are in equilibrium. B temperature pressure A C D solidliquid gas..

127. Phase Diagrams Usually, the melting point is only slightly affected by pressure. For this reason, the melting point curve, AB, is nearly vertical. B temperature pressure A C D solidliquid gas..

128. Phase Diagrams If a liquid is more dense than its solid, the curve leans slightly to the left, causing the melting point to decrease with pressure. B temperature pressure A C D solidliquid gas..

129. Phase Diagrams If a liquid is less dense than its solid, the curve leans slightly to the right, causing the melting point to increase with pressure. B temperature pressure A C D solidliquid gas..

130. Phase Diagrams Curve AC, which divides the liquid region from the gaseous region, represents the boiling points of the liquid for various pressures. B temperature pressure A C D solidliquid gas..

131. Phase Diagrams Curve AD, which divides the solid region from the gaseous region, represents the vapor pressures of the solid at various temperatures. B temperature pressure A C D solidliquid gas..

132. Phase Diagrams The curves intersect at A, the triple point, which is the temperature and pressure where three phases of a substance exist in equilibrium. B temperature pressure A C D solidliquid gas..

133. Phase Diagrams The curves intersect at A, the triple point, which is the temperature and pressure where three phases of a substance exist in equilibrium. B temperature pressure A C D solidliquid gas..

134. Phase Diagrams The temperature above which the liquid state of a substance no longer exists regardless of pressure is called the critical temperature. B temperature pressure A C D solidliquid gas.. T crit

135. Phase Diagrams The vapor pressure at the critical temperature is called the critical pressure. Note that curve AC ends at the critical point, C. B temperature pressure A C D solidliquid gas.. T crit P crit

136. Phase Diagram for Carbon Dioxide Copyright © Cengage Learning. All rights reserved 136

137. Phase Diagram for Water Copyright © Cengage Learning. All rights reserved 137

138. As intermolecular forces increase, what happens to each of the following? Why? – Boiling point – Viscosity – Surface tension – Enthalpy of fusion – Freezing point – Vapor pressure – Heat of vaporization CONCEPT CHECK!