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Chapter 13 Properties of Solutions

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Title: Chapter 13 Properties of Solutions


1
Chapter 13Properties of Solutions
Chemistry, The Central Science, 10th
edition Theodore L. Brown H. Eugene LeMay, Jr.
and Bruce E. Bursten
  • John D. Bookstaver
  • St. Charles Community College
  • St. Peters, MO
  • ? 2006, Prentice Hall, Inc.

2
December 10
  • The solution process
  • Why a solution forms?
  • Chapter HW
  • 1,3,4,6
  • Solution process13, 15
  • Saturated solutions Factors affecting
    solubility19, 21, 25, 27, 29, 31

3
Section 13.1The Solution process
  • Energy Changes and Solution Formation
  • Solution Formation, Spontaneity and Disorder.
  • Solution Formation and Chemical Reactions

4
Solutions
  • Solutions are homogeneous mixtures of two or more
    pure substances.
  • In a solution, the solute (present in smaller
    amount) is dispersed uniformly throughout the
    solvent (present in largest amount).

5
Solutions
  • The intermolecular forces between solute and
    solvent particles must be strong enough to
    compete with those between solute particles and
    those between solvent particles.

6
How Does a Solution Form?
  • As a solution forms, the solvent pulls solute
    particles apart and surrounds, or solvates, them.

7
How Does a Solution Form
  • If an ionic salt is soluble in water, it is
    because the ion-dipole interactions are strong
    enough to overcome the lattice energy of the salt
    crystal.

8
Energy Changes and SolutionFormation
  • Three processes affect the energetic of the
    process
  • Separation of solute particles D H1
  • Separation of solvent particles D H2
  • New interactions between solute and solvent D
    H3

9
  • Energy Changes and Solution Formation
  • We define the enthalpy change in the solution
    process as
  • ?Hsoln ?H1 ?H2 ?H3.
  • ?Hsoln can either be positive or negative
    depending on the intermolecular forces.

10
  • Breaking attractive intermolecular forces is
    always endothermic.
  • Forming attractive intermolecular forces is
    always exothermic.

11
Energy Changes in Solution
  • The enthalpy change of the overall process
    depends on ?H for each of these steps.

12
Why Do Endothermic Processes Occur?
  • Things do not tend to occur spontaneously (i.e.,
    without outside intervention) unless the energy
    of the system is lowered.

13
  • To determine whether ?Hsoln is positive or
    negative, we consider the strengths of all
    solute-solute and solute-solvent interactions
  • ?H1 and ?H2 are both positive.
  • ?H3 is always negative.
  • It is possible to have either ?H3 gt (?H1 ?H2)
    or ?H3 lt (?H1 ?H2).

14
  • Examples
  • NaOH added to water has ?Hsoln -44.48 kJ/mol.
  • NH4NO3 added to water has ?Hsoln 26.4 kJ/mol.
  • Rule LIKE DISSOLVES LIKE!!!
  • polar solvents dissolve polar solutes. Non-polar
    solvents dissolve non-polar solutes. Why?
  • If ?Hsoln is too endothermic a solution will not
    form.
  • NaCl in gasoline the ion-dipole forces are weak
    because gasoline is non-polar. Therefore, the
    ion-dipole forces do not compensate for the
    separation of ions.
  • Water in octane water has strong H-bonds. There
    are no attractive forces between water and octane
    to compensate for the H-bonds.

15
Why Do Endothermic Processes Occur?
  • Yet we know that in some processes, like the
    dissolution of NH4NO3 in water, heat is absorbed,
    not released.

16
Enthalpy Is Only Part of the Picture
  • The reason is that increasing the disorder or
    randomness (known as entropy) of a system tends
    to lower the energy of the system.

17
Entropy- Disorder
  • So even though enthalpy may increase, the
    overall energy of the system can still decrease
    if the system becomes more disordered.

18
Solution formation -Spontaneity
  • Spontaneous change tend to occur if the process
    results in
  • a) lower energy for the whole system
  • So the changes with D H lt 0 are favored.
  • b) an increase in the total disorder, randomnes,
    degree of dispersal or entropy D S gt 0

19
  • A solution will form except in the cases that the
    attraction between solute-solute/solvent-solvent
    are too strong compared with the solute-solvent
    attractions.
  • Solution formation always increase the Entropy of
    the system.

20
Solution formation and chemical reaction
  • Dissolution is a physical changeyou can get back
    the original solute by evaporating the solvent.
  • If you cant, the substance didnt dissolve, it
    reacted.

21
Student, Beware!
  • Just because a substance disappears when it
    comes in contact with a solvent, it doesnt mean
    the substance dissolved.

22
  • Solution Formation and Chemical Reactions
  • Consider
  • Ni(s) 2HCl(aq) ? NiCl2(aq) H2(g).
  • Note the chemical form of the substance being
    dissolved has changed (Ni ? NiCl2).
  • When all the water is removed from the solution,
    no Ni is found (only NiCl26H2O). Therefore, Ni
    dissolution in HCl is a chemical process.
  • NiCl26H2O is a hydrate that contains Ni2 ions.

23
  • Example
  • NaCl(s) H2O (l) ? Na(aq) Cl-(aq).
  • When the water is removed from the solution, NaCl
    is found. Therefore, NaCl dissolution is a
    physical process.

24
  • Section 13.3
  • Factors Affecting Solubility

25
Types of Solutions
  • Saturated
  • Solvent holds as much solute as is possible at
    that temperature.
  • Dissolved solute is in dynamic equilibrium with
    solid solute particles.

26
Types of Solutions
  • Unsaturated
  • Less than the maximum amount of solute for that
    temperature is dissolved in the solvent.

27
Types of Solutions
  • Supersaturated
  • Solvent holds more solute than is normally
    possible at that temperature.
  • These solutions are unstable crystallization can
    usually be stimulated by adding a seed crystal
    or scratching the side of the flask.
  • NaC2H3O2 Sodium acetate usually forms
    supersaturated solutions.

28
Factors Affecting Solubility
  • Solute-Solvent interactions
  • Pressure effects (only for gases)
  • Temperature effects

29
Factors Affecting Solubility
  • Chemists use the axiom
  • like dissolves like
  • Polar substances tend to dissolve in polar
    solvents.
  • Nonpolar substances tend to dissolve in nonpolar
    solvents.

30
Factors Affecting Solubility
  • The more similar the intermolecular attractions,
    the more likely one substance is to be soluble in
    another.

31
Factors Affecting Solubility
  • Glucose (which has hydrogen bonding) is very
    soluble in water, while cyclohexane (which only
    has dispersion forces) is not.

32
Factors Affecting Solubility
  • Solute-Solvent Interaction
  • Polar substances tend to dissolve in polar
    solvents.
  • Miscible liquids mix in any proportions.
  • Immiscible liquids do not mix.
  • Intermolecular forces are important water and
    ethanol are miscible because the broken hydrogen
    bonds in both pure liquids are re-established in
    the mixture.
  • The number of carbon atoms in a chain affect
    solubility the more C atoms the less soluble in
    water.

33
  • Solute-Solvent Interaction
  • The number of -OH groups within a molecule
    increases solubility in water.
  • Generalization like dissolves like.
  • The more polar bonds in the molecule, the better
    it dissolves in a polar solvent.
  • The less polar the molecule the less it dissolves
    in a polar solvent and the better is dissolves in
    a non-polar solvent.

34
  • Example Place the following substances in order
    of increasing solubility in water

5
1
3
2
4
35
  • Example Place the following substances in order
    of increasing solubility in hexane (C6H14)

5
1
4
3
2
36
Solute-Solvent Interaction
37
Solute-Solvent Interaction
38
  • Solute-Solvent Interaction
  • Network solids do not dissolve because the strong
    intermolecular forces in the solid are not
    re-established in any solution.
  • Pressure Effects
  • Solubility of a gas in a liquid is a function of
    the pressure of the gas.

39
Gases in Solution
  • In general, the solubility of gases in water
    increases with increasing mass.
  • Larger molecules have stronger dispersion forces.

40
Gases in Solution
  • The solubility of liquids and solids does not
    change appreciably with pressure.
  • The solubility of a gas in a liquid is directly
    proportional to its pressure.

41
Henrys Law
  • Sg kPg
  • where
  • Sg is the solubility of the gas
  • k is the Henrys law constant for that gas in
    that solvent
  • Pg is the partial pressure of the gas above the
    liquid.

42
Henrys Law Constant
  • Is different for each solute-gas pair.
  • Varies with temperature

43
  • The higher the pressure, the more molecules of
    gas are close to the solvent and the greater the
    chance of a gas molecule striking the surface and
    entering the solution.
  • Therefore, the higher the pressure, the greater
    the solubility.
  • The lower the pressure, the fewer molecules of
    gas are close to the solvent and the lower the
    solubility.

44
  • Example What is the concentration of CO2 in
    water in a soda bottled under a pressure of 20.0
    atm of CO2?
  • (k 3.1 x 10-2 mol L-1 atm-1)
  • 0.62 mol L-1 or 0.62 M

45
  • Pressure Effects
  • Carbonated beverages are bottled with a partial
    pressure of CO2 gt 1 atm.
  • As the bottle is opened, the partial pressure of
    CO2 decreases and the solubility of CO2
    decreases.
  • Therefore, bubbles of CO2 escape from solution.

46
Temperature
  • Generally, the solubility of solid solutes in
    liquid solvents increases with increasing
    temperature.
  • Note the exception
  • Ce2(SO4)3

47
Temperature
  • The opposite is true of gases
  • Carbonated soft drinks are more bubbly if
    stored in the refrigerator.
  • Warm lakes have less O2 dissolved in them than
    cool lakes.

48
Ways of Expressing Concentrations of Solutions
49
Homework
  • 33, 35, 37, 41, 45, 47, 49

50
Concentrations
  • Qualitative Expressions
  • Dilute Concentrate
  • Quantitative Expressions
  • Molarity-Molality
  • by mass, ppm,ppb
  • Mole Fraction

51
Mass Percentage
? 100
  • Mass of A

52
  • Find the percent of KCl in a solution that
    contains .005 g of KCl in 50 g of solution
  • Express the result in ppm and ppb

53
Parts per Million andParts per Billion
Parts per Million (ppm)
? 106
  • ppm

Parts per Billion (ppb)
? 109
ppb
54
Mole Fraction (X)
  • In some applications, one needs the mole fraction
    of solvent, not solutemake sure you find the
    quantity you need!
  • REMEMBER THE SUM OF THE MOLE FRACTIONS OF ALL
    COMPONENTS OF THE SOLUTION 1

55
  • Find the mole fraction of CH3OH in a solution
    that contains 32 gr of methanol in 36 gr of
    water.
  • What is the mole fraction of water in that
    solution

56
Molarity (M)
  • Because volume is temperature dependent, molarity
    can change with temperature.

57
Molality (m)
  • Because both moles and mass do not change with
    temperature, molality (unlike molarity) is not
    temperature dependent.

58
Changing Molarity to Molality
  • If we know the density of the solution, we can
    calculate the molality from the molarity, and
    vice versa.

59
  • Example - 1.00 g of NaCl is dissolved in 50.0 g
    of H2O, to make a solution with a total volume of
    50.7 mL. Calculate the molarity, mass percent,
    mole fraction, molality, ppm, and ppb of NaCl in
    this solution.
  • 0.338 M 1.96
  • X 0.00613 0.342 m
  • 19600 ppm 19600000 ppb

60
December 12
  • Colligative properties.
  • HW 55, 57, 59, 61, 63, 65
  • Pre lab for experiment 11 due wednesday in a
    separate paper.
  • Review questions from Pearson site due friday
    before test
  • Test on solutions on friday 16

61
Colligative Properties
  • Changes in colligative properties depend only on
    the number of solute particles present, not on
    the identity of the solute particles.
  • Among colligative properties are
  • Vapor pressure lowering
  • Boiling point elevation
  • Melting point depression
  • Osmotic pressure

62
Vapor Pressure
  • Because of solute-solvent intermolecular
    attraction, higher concentrations of nonvolatile
    solutes make it harder for solvent to escape to
    the vapor phase.

63
Vapor Pressure
  • Therefore, the vapor pressure of a solution is
    lower than that of the pure solvent.
  • The amount of vapor pressure lowering depends on
    the amount of solute.

64
Raoults Law
  • PA XAP?A
  • where
  • PA is the vapor pressure of the solution
  • XA is the mole fraction of compound A
  • P?A is the normal vapor pressure of A at that
    temperature
  • NOTE This is one of those times when you want
    to make sure you have the vapor pressure of the
    solvent.

65
  • Lowering Vapor Pressure
  • Raoults Law PA is the vapor pressure of the
    solution, PA? is the vapor pressure of pure
    solvent, and ?A is the mole fraction of A, then
  • Recall Daltons Law
  • Ptotal P1 P2 c1Po1 c2Po2

66
  • Ideal solution one that obeys Raoults law.
  • Raoults law breaks down when the solvent-solvent
    and solute-solute intermolecular forces are
    greater than solute-solvent intermolecular
    forces.
  • Example - Calculate the Vapor Pressure of a
    solution prepared by dissolving 50.0 g of sugar
    (C12H22O11) in 200. g of H2O. (Vapor Pressure of
    pure H2O 23.76 torr)
  • 23.55 torr

67
  • Example
  • Calculate the vapor pressure of a solution of
    25.0 g of H2O and 30.0 g of C2H5OH at 25o C.
  • Vapor pressures
  • H2O 23.76 torr
  • C2H5OH 64.84 torr
  • 36.9 torr

68
  • Example
  • What is the composition of a pentane-hexane
    solution that has a vapor pressure of 350 torr at
    25ºC?
  • The vapor pressures at 25ºC are
  • pentane 511 torr
  • hexane 150 torr
  • What is the composition of the vapor?

69
FREEZING POINT DEPRESION
  • When a solute is dissolved in a solvent, the
    solvent particles form a shell around the solute
    particles. When the temperature decreases, the
    solute particles disrupt the crystal formation of
    the solvent because of the shells of hydration,
    therefore more kinetic energy must be removed
    from the solution in order for the solvent to
    solidify, causing the freezing point to depress.

70

71
Freezing Point Depression
  • The change in freezing point can be found
    similarly
  • ?Tf Kf ? m
  • Here Kf is the molal freezing point depression
    constant of the solvent.

?Tf is subtracted from the normal freezing point
of the solvent.
72
Boiling Point Elevation
  • The change in boiling point is proportional to
    the molality of the solution
  • ?Tb Kb ? m
  • where Kb is the molal boiling point elevation
    constant, a property of the solvent.

?Tb is added to the normal boiling point of the
solvent.
73
Boiling Point Elevation and Freezing Point
Depression
  • Nonvolatile solute-solvent interactions also
    cause solutions to have higher boiling points and
    lower freezing points than the pure solvent.

74
  • Freezing Point Depression
  • At 1 atm (normal boiling point of pure liquid)
    there is no depression by definition
  • When a solution freezes, almost pure solvent is
    formed first.
  • Therefore, the sublimation curve for the pure
    solvent is the same as for the solution.
  • Therefore, the triple point occurs at a lower
    temperature because of the lower vapor pressure
    for the solution.

75
  • The melting-point (freezing-point) curve is a
    near-vertical line from the triple point.
  • The solution freezes at a lower temperature (?Tf)
    than the pure solvent.
  • Decrease in freezing point (?Tf) is directly
    proportional to molality (Kf is the molal
    freezing-point-depression constant)

76
December 14
  • Colligative properties
  • Review for lab 11
  • Will do the lab Friday. Prelab due tomorrow

77
Boiling Point Elevation and Freezing Point
Depression
  • Note that in both equations, ?T does not depend
    on what the solute is, but only on how many
    particles are dissolved.
  • ?Tb Kb ? m
  • ?Tf Kf ? m

78
Colligative Properties of Electrolytes
  • Since these properties depend on the number of
    particles dissolved, solutions of electrolytes
    (which dissociate in solution) should show
    greater changes than those of nonelectrolytes.

79
Colligative Properties of Electrolytes
  • However, a 1 M solution of NaCl does not show
    twice the change in freezing point that a 1 M
    solution of methanol does.

80
vant Hoff Factor
  • One mole of NaCl in water does not really give
    rise to two moles of ions.

81
vant Hoff Factor
  • Some Na and Cl- reassociate for a short time,
    so the true concentration of particles is
    somewhat less than two times the concentration of
    NaCl.

82
The vant Hoff Factor
  • Reassociation is more likely at higher
    concentration.
  • Therefore, the number of particles present is
    concentration dependent.

83
i vant Hoff factor number of particles
produced when a substance dissolves For nonionic
substances, i1 For ionic substances, i is the
number of ions produced per formula unit that
dissolves. NaCl, i 2 Na3PO4 i 4 Na3PO4
? 3 Na PO43-
84
Explain
  • Sodium chloride may be spread on an icy sidewalk
    in order to melt the ice equimolar amounts of
    calcium chloride are even more effective. (10
    pts)

85
  • Deviations from Raoults Law
  • If Solvent has a strong affinity for solute (H
    bonding).
  • Lowers solvents ability to escape.
  • Lower vapor pressure than expected.
  • Negative deviation from Raoults law.
  • ?Hsoln is large and negative exothermic.
  • Endothermic ?Hsoln indicates positive deviation.

86
The vant Hoff Factor
  • We modify the previous equations by multiplying
    by the vant Hoff factor, i
  • ?Tf Kf ? m ? i

87
Osmosis
  • Some substances form semipermeable membranes,
    allowing some smaller particles to pass through,
    but blocking other larger particles.
  • In biological systems, most semipermeable
    membranes allow water to pass through, but
    solutes are not free to do so.

88
Osmosis
  • In osmosis, there is net movement of solvent
    from the area of higher solvent concentration
    (lower solute concentration) to the are of lower
    solvent concentration (higher solute
    concentration).

89
Osmotic Pressure
  • The pressure required to stop osmosis, known as
    osmotic pressure, ?, is

where M is the molarity of the solution
If the osmotic pressure is the same on both sides
of a membrane (i.e., the concentrations are the
same), the solutions are isotonic.
90
Osmosis in Blood Cells
  • If the solute concentration outside the cell is
    greater than that inside the cell, the solution
    is hypertonic.
  • Water will flow out of the cell, and crenation
    results.

91
Osmosis in Cells
  • If the solute concentration outside the cell is
    less than that inside the cell, the solution is
    hypotonic.
  • Water will flow into the cell, and hemolysis
    results.

92
  • Hemolysis
  • red blood cells placed in a hypotonic solution
  • there is a higher solute concentration in the
    cell
  • osmosis occurs and water moves into the cell.
  • The cell bursts.
  • To prevent crenation or hemolysis, IV
    (intravenous) solutions must be isotonic.

93
  • Cucumber placed in NaCl solution loses water to
    shrivel up and become a pickle.
  • Limp carrot placed in water becomes firm because
    water enters via osmosis.
  • Salty food causes retention of water and swelling
    of tissues (edema).
  • Water moves into plants through osmosis.
  • Salt added to meat or sugar to fruit prevents
    bacterial infection (a bacterium placed on the
    salt will lose water through osmosis and die).

94
  • Active transport is the movement of nutrients and
    waste material through a biological system.
  • Active transport is not spontaneous.

95
  • Example
  • What is the osmotic pressure of a solution of
    7.95 g of NaCl in 50.0 mL of an aqueous solution
    at 75C?
  • 155 atm
  • 118,000 mm Hg

96
Molar Mass from Colligative Properties
  • We can use the effects of a colligative property
    such as osmotic pressure to determine the molar
    mass of a compound.

97
  • One major application of vapor pressure lowering
    and colligative properties is in molar mass
    problems
  • 1. An aqueous solution contains 1.00 g/L of a
    detergent. The osmotic pressure of this solution
    at 25C is 17.8 torr. What is the molar mass of
    the detergent?

98
  • 1.008 g of a compound was dissolved in 11.38 mL
    of benzene (d0.879 g/mL) and the solution froze
    at 4.37C. What is the molar mass of the
    compound?
  • Tf(benzene) 5.48C
  • Kf(benzene) 5.12C/molal

99
3. 3.101 g of a nonvolatile nonelectrolyte were
dissolved in 100. g of CCl4. The vapor pressure
of CCl4 was lowered by 1.85. What is the molar
mass of the solute?
100
Colloids
  • Colloids are suspensions in which the suspended
    particles are larger than molecules but too small
    to drop out of the suspension due to gravity.
  • Particle size 10 to 2000 Å.
  • There are several types of colloid
  • aerosol (gas liquid or solid, e.g. fog and
    smoke),
  • foam (liquid gas, e.g. whipped cream),
  • emulsion (liquid liquid, e.g. milk),
  • sol (liquid solid, e.g. paint),

101
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102
  • solid foam (solid gas, e.g. marshmallow),
  • solid emulsion (solid liquid, e.g. butter),
  • solid sol (solid solid, e.g. ruby glass).
  • Tyndall effect ability of a Colloid to scatter
    light. The beam of light can be seen through the
    colloid.

103
Tyndall Effect
  • Colloidal suspensions can scatter rays of light.
  • This phenomenon is known as the Tyndall effect.

104
Colloids in Biological Systems
  • Some molecules have a polar, hydrophilic
    (water-loving) end and a nonpolar, hydrophobic
    (water-hating) end.

105
Colloids in Biological Systems
  • Sodium stearate is one example of such a
    molecule.

106
  • Sodium stearate has a long hydrophobic tail
    (CH3(CH2)16-) and a small hydrophobic head
    (-CO2-Na).
  • The hydrophobic tail can be absorbed into the oil
    drop, leaving the hydrophilic head on the
    surface.
  • The hydrophilic heads then interact with the
    water and the oil drop is stabilized in water.

107
Colloids in Biological Systems
  • These molecules can aid in the emulsification of
    fats and oils in aqueous solutions.

108
  • Hydrophilic and Hydrophobic Colloids
  • Focus on colloids in water.
  • Water loving colloids hydrophilic.
  • Water hating colloids hydrophobic.
  • Molecules arrange themselves so that hydrophobic
    portions are oriented towards each other.
  • If a large hydrophobic macromolecule (giant
    molecule) needs to exist in water (e.g. in a
    cell), hydrophobic molecules embed themselves
    into the macromolecule leaving the hydrophilic
    ends to interact with water.

109
  • Typical hydrophilic groups are polar (containing
    C-O, O-H, N-H bonds) or charged.
  • Hydrophobic colloids need to be stabilized in
    water.
  • Adsorption when something sticks to a surface we
    say that it is adsorbed.
  • If ions are adsorbed onto the surface of a
    colloid, the colloids appears hydrophilic and is
    stabilized in water.
  • Consider a small drop of oil in water.
  • Add to the water sodium stearate.

110
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111
Colloids
112
  • Most dirt stains on people and clothing are
    oil-based. Soaps are molecules with long
    hydrophobic tails and hydrophilic heads that
    remove dirt by stabilizing the colloid in water.
  • Bile excretes substances like sodium stereate
    that forms an emulsion with fats in our small
    intestine.
  • Emulsifying agents help form an emulsion.

113
  • Removal of Colloidal Particles
  • Colloid particles are too small to be separated
    by physical means (e.g. filtration).
  • Colloid particles are coagulated (enlarged) until
    they can be removed by filtration.
  • Methods of coagulation
  • heating (colloid particles move and are attracted
    to each other when they collide)
  • adding an electrolyte (neutralize the surface
    charges on the colloid particles).

114
  • Dialysis using a semipermeable membranes
    separate ions from colloidal particles.
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