Mod Chem 12

Links to figures and tables have been broken due to copyright laws.

Chapter 12 Liquids and Solids

Liquids

Least common state of matter in the universe -- narrow range of temperatures and pressures.
1. Properties of Liquids and the Kinetic-Molecular Theory
  
  a) definite volume
  b) takes the shape of its container
  c) particles in constant motion
  
  in liquid the particles are closer than in gases and have more effective attractive forces
  
  in liquid the particles have lower mobility because of the closeness of adjacent molecules
  
  fluid - definition
  
  flowing downhill
  flowing uphill e.g. helium
  1. Relatively High Density
    
    most liquids are thousands of times denser than their gases at normal temperature and pressure
    
    because of the closeness of the particles
    
    water is an exception of most substances being more dense as a solid than as a liquid
    
    at same temperature, different liquids can vary greatly in density e.g. Figure 12-1 page 364
  2. Relative Incompressibility
    
    at 20 degrees Celsius and at a pressure of 1000 atm pressure, the volume of water decreases by only 4% -- typical of liquids as well as solids -- due to closeness of particles in both liquids and solids
    
    because of the closeness of liquid molecules when pressure is exerted on them, that pressure is transmitted in all directions
  3. Ability to Diffuse
    
    Liquids, like gases, diffuse and mix with other liquids.
    
    Figure 12-2 page 364
    
    Diffusion is due to constant random motion of particles, but much slower in liquids than in gases because of the closeness of particles.
    
    Also slower because of the attractive forces present in liquids.
    
    At higher temperature, the diffusion of liquids increases because of the increased speed of the particles.
  4. Surface Tension
    
    Surface tension - definition
    
    Due to attractive forces of particles and is directly proportional to the attractive forces.
    
    Water has a higher surface tension than many liquids because of its hydrogen bonding.
    
    Molecules at the surface act differently than molecules in the body of the liquid.
    
    Surface tension is why liquid drops have a spherical shape -- a sphere has the smallest surface area for a given volume.
    
    Figure 12-3 page 365
    
    Capillary action - definition
    
    Closely related to surface tension.
    
    Depends on attraction between liquid and the surface of the solid, usually a tube of some kind.
    
    Continues until capillary action is balanced by the pull of gravity.
    
    Can happen between water molecules and paper fibers such as in Figure 12-4 page 365
    
    Movement of water in plants.
    
    Meniscus
  5. Evaporation and Boiling
    
    Vaporization - definition
    
    Evaporation is a form of vaporization.
    
    Evaporation - definition
    
    Liquid bromine added to bottle, and soon have vapor above the liquid.
    
    Figure 12-5 page 366
    
    perfume to wrist area
    
    Each particle in a liquid has a different kinetic energy; a molecule with higher than average kinetic energy that is also at the surface of the liquid can overcome the attractive forces of the particles beside and beneath it and escape from the liquid and goes into the gaseous state.
    
    Important in nature - evaporation of sea water leaves behind the salt which increases the concentration of the salt in the sea.
    
    Evaporation of water from the surface of the earth is what comes back down as rain and snow.
    
    Perspiration -- keeps us cool by removing high energy water molecules from our skin which takes heat away from our body.
    
    Boiling is when a liquid turns into a vapor in the body of the liquid and forms a vapor bubble in the body of the liquid. More on boiling later.
  6. Formation of Solids
    
    Cooling a liquid sufficiently allows attractive forces to pull the particles into an even more orderly arrangement.
    
    Freezing - definition
    
    All liquids freeze e.g. water at 0 degrees Celsius; paraffin (candle wax) at room temperature; ethanol at -115 degrees Celsius.
    
    Homework: Web Site, Chapter 12, Liquids
2. Solids
  
  definite shape
  definite volume
  1. Properties of Solids and the Kinetic-Molecular Theory
    
    particles more closely packed than liquid -- thus stronger intermolecular forces (dipole-dipole, London dispersion forces, hydrogen bonding)
    
    particles in relatively fixed positions
    
    only vibrational movement
    
    particles more orderly than other physical states
    
    Figure 12-6 page 367 -- physical appearance of solids, liquids, gases
    
    Two types of solids: a) crystalline solids which consist of crystals - definition; b) amorphous solids - definition
    1. Definite Shape and Volume
      
      maintain definite shape without a container
      
      crystalline solids have regular geometric arrangement of particles reflecting of the internal structure
      
      amorphous solids have a definite shape but not the regular geometric arrangement of particles
      
      volume of solids change little with changes in temperature or pressure
      
      solids have a definite volume because the particles are packed closely an have very little empty space, thus little chance of compression
    2. Definite Melting Point
      
      Melting - definition
      
      Melting Point - definition
      
      When a solid melts the kinetic energy of the particles overcomes the attractive forces holding the particles together
      
      Crystalline solids have a definite melting point. Amorphous solids have a temperature range which is their melting point.
      
      Amorphous solids are sometimes called supercooled liquids.
      
      Supercooled liquids - definition
      
      Particles in supercooled liquids are arranged randomly as in a liquid but they are not true liquids because the particles are not constantly changing their positions.
    3. High Density and Incompressibility
      
      Solids are slightly denser than liquids.
      
      solid hydrogen is the least dense solid and osmium is the most dense
      
      less compressible than liquids
      
      wood and cork are compressible because of air trapped in pores and it is the pores that are compressed
    4. Low Rate of Diffusion
      
      diffusion can occur in solids but only over long periods of time and is a million times slower than diffusion in liquids
  2. Crystalline Solids
    
    can be a single crystals or groups of crystals fused together
    
    crystal structure - definition
    
    lattice - definition
    
    unit cell - definition
    
    Each crystal lattice contains many unit cells packed together - figure 12-7 page 368
    
    A crystal and its unit cells can have any one of seven type of symmetry and allows us to classify crystal by their shape -- figure 12-8 page 369
    
    No need to memorize these crystal symmetries.
    1. Binding Forces in Crystals
      
      can also describe crystals in terms of the types of particles and the types of chemical bonding between particles -- table 12-1 page 370
      
      Four type of crystals based on this:
      
      a) ionic crystals: particles are positive and negative ions; ions can be monatomic or polyatomic; usually group 1 or 2 elements with group 17 or 17 elements; binding forces are attractive forces between positive and negative ions; properties are hard, brittle, high melting points, good insulators.
      
      b) covalent network crystals: particles are single atoms; binding forces are covalent bonds; e.g. diamond, C_x, quartz, (SiO₂)_x, Figure 12-9, page 371, silicon carbide, (SiC)_x, and many oxides of transition metals.
      
      hard and brittle, high melting points, usually nonconductors or semiconductors
      
      c) metallic crystals: particles are metal atom kernel and sea of valence electrons;
      
      high electrical conductivity, melting points vary -- table 12-1 page 370
      
      d) covalent molecular crystals: particles are covalently bonded molecules held by intermolecular attractive forces; if non polar, then only London dispersion forces hold the molecules together, e.g. hydrogen molecule, methane, benzene; in polar covalent molecular crystals the molecules are held together by London dispersion forces, dipole-dipole forces and sometimes hydrogen bonds e.g. Water, ammonia;
      
      low melting points; easily vaporized, relatively soft, good insulators.
  3. Amorphous Solids
    
    without shape
    
    do not have a regular, natural shape as in crystals
    
    hold their shape for long time but some can flow e.g. very old window glass and other types of glass.
    
    Homework: Web Site, Chapter 12, Solids
3. Changes of State
  
  table 12-2, page 372 different changes in states and their names
4. Equilibrium
  
  Equilibrium - definition
  
  a closed system means matter can not enter or leave but energy can
  1. Equilibrium and Changes of State
    
    figure 12-10 page 373
    
    initially just a single phase - liquid
    
    phase - definition
    
    surface molecules evaporate and enter gaseous state above the liquid
    
    some of the vapor molecules then will enter the liquid state
    
    condensation - definition
    
    initially there are no vapor molecules, only liquid molecules
    
    as time goes on the number of vapor molecules increases and eventually some of the vapor molecules enter the liquid state figure 12-10 b
    
    at some point in time the number of liquid molecules entering the vapor state is the same as the number of vapor molecules entering the liquid state -- then we have equilibrium. figure 12-10 c
    
    the process of vapor = liquid continues once equilibrium is reached
    
    Equilibrium is based on the RATE of vapor molecules becoming liquid equal to the rate of liquid molecules becoming vapor -- not on the amounts of vapor and liquid at equilibrium
    
    once equilibrium is reached and maintained, the amount of vapor and liquid remains the same because the rate of conversion from one to the other is the same
  2. An Equilibrium Equation
    
    liquid + heat ---> vapor
    
    vapor ---> liquid + heat
    
    liquid + heat = vapor
    
    two opposing arrows or equal sign
    
    forward reaction -- left to right
    
    reverse reaction -- right to left
  3. LeChatelier's Principle
    
    LeChatelier's Principle - statement
    
    a stress can be a change in concentration, pressure, temperature
  4. Equilibrium and Temperature
    
    given: liquid + heat = vapor
    
    and the temperature is raised from 25 to 35 degrees Celsius
    
    fwd reaction is endothermic, reverse is exothermic; an increase in temperature favors the endothermic reaction so the equilibrium shifts to the RIGHT to relieve the stress which means that the fwd reaction occurs faster than the reverse because of the increase in temperature; eventually the reverse reaction catches up and a new equilibrium is reached with both the fwd and rev rxns occurring at a higher rate than at 25 degrees Celsius
    
    at the higher temperature, the concentration of vapor (the product of the favored reaction) is higher than it was at the lower temperature -- concentration here refers to the amount of vapor at the new equilibrium compared to the volume of the container
    
    take original equilibrium and lower the temperature from 25 to 15 degrees Celsius -- describe what happens
  5. Equilibrium and Concentration
    
    given: liquid + heat = vapor
    
    increase the volume available to the system: more volume means the same number of molecules of vapor in more volume -- decreased concentration of vapor molecules -- the change from vapor to liquid slows while the change from liquid to vapor remains the same i.e. the rate of liquid to vapor is now higher than the rate of vapor to liquid -- we say that the fwd reaction is favored.
    
    table 12-3 page 375
5. Equilibrium Vapor Press of a Liquid
  
  equilibrium vapor pressure - definition
  
  figure 12-11 page 376 - vapor pressure setting up
  
  figure 12-12 page 377 - vapor pressure curves
  
  equilibrium vapor pressure depends on
  a) what the liquid is
  b) temperature
  
  notice from the graph that an increase in temperature does not increase the vapor pressure proportionally -- not a straight line.
  1. Equilibrium Vapor Pressure and the Kinetic Molecular Theory
    
    increasing the temperature of a liquid increases its average kinetic energy
    
    an increase in average kinetic energy increases the number of molecules that can escape from the liquid to the vapor state
    
    an increase in the number of vapor molecules increases the vapor pressure
  2. Volatile and Nonvolatile Liquids
    
    the stronger the attractive forces between the molecules in a liquid the lower will be its vapor pressure at any given temperature; the weaker the forces of attraction, the high will be its vapor pressure at any given temperature
    
    volatile liquids - definition
6. Boiling
  
  boiling - definition
  
  boiling point - definition
  
  the lower the atmospheric pressure the lower the boiling point - affects cooking
  
  during boiling the temperature is constant -- i.e. as long as liquid and vapor coexist the temperature is constant
  
  heating curve - temperature vs heat
  
  heat absorbed during boiling goes toward converting the liquid molecules into the vapor state i.e. to overcome attractive forces holding the molecules in the liquid state not toward increasing the average kinetic energy
  
  increasing the pressure above a boiling liquid -- pressure cooker
  
  vacuum evaporator -- used to remove water from milk and sugar solutions without affecting the milk or sugar because of the lower temperatures
  
  normal boiling point - definition
  
  figure 12-12 page 377
  1. Energy and Boiling
    
    To keep a liquid boiling you must continually supply heat.
    
    We continue to heat, the liquid continues to boil but its temperature remains constant.
    
    Heat added during boiling goes to overcome attractive forces between molecules so they can enter the gaseous state.
  2. Molar Heat of Vaporization
    
    molar heat of vaporization - definition
    
    related to the attractive forces in the liquid - greater attractive forces, greater the size of the molar heat of vaporization
    
    characteristic of the liquid
    
    water's is high because of the hydrogen bonding
    
    makes water a good cooling agent
    
    figure 12-13 page 379
7. Freezing and Melting
  
  freezing involves the loss of heat energy by the liquid and can be represented by
  
  liquid ---> solid + heat energy
  
  normal freezing point - definition
  
  liquid and solid are in equilibrium at the freezing point - heating curve - constant temperature
  
  at the freezing point, the particles of the liquid and the solid have the same average kinetic energy so energy loss during freezing is a loss of potential energy
  
  as long as solid and liquid are present the temperature remains the same
  1. Molar Heat of Fusion
    
    molar heat of fusion - definition
    
    heat absorbed increases the potential energy of the solid as its particles are pulled apart, overcoming the attractive forces holding them together
    
    size depends on the attraction between the particles of the solid
  2. Sublimation and Deposition
    
    at the proper low temperature and pressure a liquid cannot exist and a solid exists in equilibrium with its vapor
    
    solid + heat energy = vapor
    
    sublimation - definition
    
    deposition - definition
    
    e.g. dry ice - solid carbon dioxide; iodine; ordinary ice sublimes slowly at temperatures lower than its melting point - explains how a thin layer of snow can eventually disappear, even if the temperature remains below zero degrees Celsius.
    
    formation of frost on a cold surface is an example of deposition
8. Phase Diagrams
  
  phase diagram - definition
  
  also shows how the states of a system change with changing temperature or pressure
  
  Figure 12-14 page 381
  
  three curves show equilibrium positions for various physical states
  
  AB: solid (ice) - vapor
  
  AC: liquid - vapor
  
  AD: liquid - solid
  
  notice negative slope of AD because ice is less dense than liquid water - increase in pressure lowers the melting point; most substances have their liquid solid curve with a positive slope
  
  Point A is the triple point
  
  triple point - definition
  
  for water is it 0.01 degrees Celsius
  
  Point C is the critical point - for water it is 373.99 degrees Celsius
  
  critical point - definition
  
  critical temperature - definition
  
  critical pressure - definition
  
  AD has a slope that indicates that ice melts at a higher temperature with decreasing pressure.
  
  Below the triple point, the temperature of sublimation decreases with decreasing pressure.
  
  Figure 12-15 summarizes all changes of states.
  
  Homework: Web Site, Chapter 12, Change of State
Water

covers about 75% of earth's surface
70-90% of the mass of living things is water
1. Structure of Water
  
  polar covalent bonds between the oxygen and each hydrogen
  
  bent geometry
  
  bond angle 105^o
  
  molecules held together by hydrogen bonding
  
  the higher the temperature the fewer molecules that are grouped together
  
  other molecules similar in size and mass to water, if they are non polar, they are gases at room temperature, viz methane, CH₄; hydrogen bonding in water
  
  ice has its molecules arranged in a hexagonal structure due to rigid hydrogen bonds; the empty spaces created is why the density of ice is less than liquid water and ice floats on water
  
  from zero to 4 degrees Celsius, heating causes the molecules to collapse into the open spaces; above four degrees the kinetic energy of the molecules due to the heating causes the molecules to start moving apart; temperature of maximum density of water is 4 degrees Celsius
2. Physical Properties of Water
  
  transparent
  odorless
  tasteless
  almost colorless
  normal freezing point is 0 degrees Celsius
  normal boiling point is 100 degrees Celsius
  molar heat of fusion of ice is 6.009 kJ/mol - relatively large
  molar heat of vaporization is 40.79 kJ/mol
  
  both are high because of hydrogen bonding
  
  steam heat
  
  Sample Problem 12-1, page 386
  
  Homework: Web Site, Chapter 12, Water

A fluid is a substance that can flow. back

Surface tension is a force that tends to pull adjacent parts of a liquid's surface together, thereby decreasing surface area to the smallest possible size. Back

Capillary action is the attraction of the surface of a liquid to the surface of a solid. Back

Vaporization is the process by which a liquid or solid changes to a gas. Back

Evaporation is the process by which particles escape from the surface of a nonboiling liquid and enter the gaseous state. Back

Freezing is the physical change of a liquid to a solid by removal of heat. Back

An amorphous solid is one in which the particles are arranged randomly. Back

A crystal is a substance in which the particles are arranged in an orderly, geometric, repeating pattern. Back

Melting is the physical change of a solid to a liquid by the addition of heat. Back

The melting point is the temperature at which a solid becomes a liquid. Back

Supercooled liquids are substances that retain certain liquid properties even at temperatures at which they appear to be solid. Back

Crystal structure is the total three-dimensional arrangement of particles of a crystal. Back

Lattice is a coordinate system used to represent the arrangement of particles in a crystal. Back

Unit cell is the smallest portion of a crystal lattice that shows the three-dimensional pattern of the entire lattice. Back

Equilibrium is a dynamic condition in which two opposing changes occur at equal rates in a closed system. Back

A phase is any part of a system that has uniform composition and properties. Back

Condensation is the process by which a gas changes to a liquid. Back

When a system at equilibrium is disturbed by application of a stress, it attains a new equilibrium position that minimizes the stress. Back

The equilibrium vapor pressure is the pressure exerted by a vapor in equilibrium with its corresponding liquid at a given temperature. Back

A volatile liquid is a liquid that evaporates readily. Back

Boiling is the conversion of a liquid to a vapor within the liquid as well as at its surface and occurs when the equilibrium vapor pressure of the liquid equals the atmospheric pressure. Back

The boiling point is the temperature at which the equilibrium vapor pressure of a liquid equals the atmospheric pressure. Back

The normal boiling point is the temperature at which a liquid will boil when the atmospheric pressure is exactly one atmosphere. Back

Molar heat of vaporization is the heat energy needed to vaporize one mole of liquid at its boiling point. Back

Normal freezing point is the temperature at which the solid and liquid are in equilibrium at 1 atm pressure. Back

Molar heat of fusion is the amount of heat energy required to melt one mole of solid at its melting point. Back

Sublimation is the change of state from a solid directly to a gas. Back

Deposition is the change of state from a gas directly to a solid. Back

A phase diagram is a graph of pressure versus temperature that shows the condition under which the phases of a substance exist. Back

The triple point of a substance indicates the temperature and pressure conditions at which the solid, liquid, and vapor of the substance can coexist at equilibrium. Back

The critical point of a substance indicates the critical temperature and critical pressure. Back

The critical temperature (t_c) is the temperature above which the substance cannot exist in the liquid state. Back

The critical pressure (P_c) is the lowest pressure at which the substance can exist as a liquid at the critical temperature. Back