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CHAPTER 12 Liquids and Solids
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Intermolecular Forces Dipole-dipole attraction Hydrogen bonds Dispersion forces Forces of attraction between different molecules rather than bonding forces within the same molecule.
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Dipole-Dipole Attraction dipole-dipole attraction: molecules with dipoles orient themselves so that “+” and “ ” ends of the dipoles are close to each other.
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Dipole Forces
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Hydrogen Bonding hydrogen bonds: dipole-dipole attraction in which hydrogen is bound to a highly electronegative atom. (F, O, N)
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Hydrogen Bonding in Water
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Hydrogen Bonding in DNA
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London Dispersion Forces Dispersion forces: relatively weak forces caused by instantaneous dipole, in which electron distribution becomes asymmetrical. The ONLY forces of attraction that exist among noble gas atoms and nonpolar molecules. (Ar, C 8 H 18 )
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London Dispersion Forces
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Boiling point as a measure of intermolecular attractive forces
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Some Properties of a Liquid Surface Tension: The resistance to an increase in its surface area (polar molecules, liquid metals).
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Some Properties of a Liquid Capillary Action: Spontaneous rising of a liquid in a narrow tube.
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Some Properties of a Liquid Viscosity: Resistance to flow (molecules with large intermolecular forces).
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Types of Solids Crystalline Solids: highly regular arrangement of their components [table salt (NaCl), pyrite (FeS 2 )].
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Types of Solids Amorphous solids: considerable disorder in their structures (glass).
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Representation of Components in a Crystalline Solid Lattice: A 3-dimensional system of points designating the centers of components (atoms, ions, or molecules) that make up the substance.
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Types of Crystalline Solids Ionic Solid: contains ions at the points of the lattice that describe the structure of the solid (NaCl).
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Types of Crystalline Solids Molecular Solid: discrete covalently bonded molecules at each of its lattice points (sucrose, ice).
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Packing in Metals Model: Packing uniform, hard spheres to best use available space. This is called closest packing. Each atom has 12 nearest neighbors.
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Closest Packing Holes
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Metal Alloys Substitutional Alloy: some metal atoms replaced by others of similar size. brass = Cu/Znbrass = Cu/Zn
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Metal Alloys (continued) Interstitial Alloy: Interstices (holes) in closest packed metal structure are occupied by small atoms. steel = iron + carbonsteel = iron + carbon
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Network Solids Composed of strong directional covalent bonds that are best viewed as a “giant molecule”.Composed of strong directional covalent bonds that are best viewed as a “giant molecule”. - brittle - do not conduct heat or electricity - carbon, silicon-based graphite, diamond, ceramics, glassgraphite, diamond, ceramics, glass
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Sulfur – S 8
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Phosphorus – P 4
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Diamond
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Graphite
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Zirconia
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Equilibrium Vapor Pressure The pressure of the vapor present at equilibrium.The pressure of the vapor present at equilibrium. Determined principally by the size of the intermolecular forces in the liquid.Determined principally by the size of the intermolecular forces in the liquid. Increases significantly with temperature.Increases significantly with temperature. Volatile liquids have high vapor pressures.Volatile liquids have high vapor pressures.
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LeChatelier’s Principle When a system at equilibrium is placed under stress, the system will undergo a change in such a way as to relieve that stress.
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When you take something away from a system at equilibrium, the system shifts in such a way as to replace what you’ve taken away. Translation: When you add something to a system at equilibrium, the system shifts in such a way as to use up what you’ve added.
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LeChatelier’s Example #1 A closed container of ice and water at equilibrium. The temperature is raised. Ice + Energy Water The equilibrium of the system shifts to the _______ to use up the added energy. right
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LeChatelier’s Example #2 A closed container of N 2 O 4 and NO 2 at equilibrium. NO 2 is added to the container. N 2 O 4 + Energy 2 NO 2 The equilibrium of the system shifts to the _______ to use up the added NO 2. left
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LeChatelier’s Example #3 A closed container of water and its vapor at equilibrium. Vapor is removed from the system. water + Energy vapor The equilibrium of the system shifts to the _______ to use up the added NO 2. left
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Water phase changes Temperature remains __________ during a phase change. constant
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Kinetic Energy
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Phase Diagram Represents phases as a function of temperature and pressure. Critical temperature: temperature above which the vapor can not be liquefied. Critical pressure: pressure required to liquefy AT the critical temperature. Critical point: critical temperature and pressure (for water, T c = 374°C and 218 atm).
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Water Water
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Phase changes by Name
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Carbon dioxide Carbondioxide
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Carbon Carbon
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Sulfur
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