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Title: Chapter 6: Sports Drink


1
Chapter 6 Sports Drink
2
Sports Drinks
  • This chapter will introduce the chemistry needed
    to understand how Sports Drinks work
  • Section 6.1 Solutions electrolytes
  • Section 6.2 Concentrations of solutions
  • Section 6.3 Acidity pH
  • Section 6.4 Solubility precipitates
  • Section 6.5 Stoichiometry
  • Section 6.7 Limiting Reactants
  • Section 6.6 Properties of solutions

3
Section 6.1Solutions Electrolytes
What are those electrolytes they say youre
replacing by drinking sports drinks?
4
Dissolving substances
  • Substances are dissolved by a process called
    hydration when the solvent is water
  • The solvent and solute need to break
    intermolecular forces within themselves- This
    requires ENERGY (ENDOTHERMIC)
  • New intermolecular forces are formed between the
    solvent and solute.- This releases
    ENERGY(EXOTHERMIC)
  • The solvent carries off the solute particles

5
Solution Formation
Endothermic
Exothermic
Endothermic
6
Dissolving Ionic Compounds
-

Solute,Ionic compound
Solvent,water
Water molecules are polar and they are attracted
to the charges of the ions in an ionic compound.

-
When the intermolecular forces are stronger
between the water and the ion than the
intramolecular forces between the ions, the water
carries away the ion.
-



-
-
7
Dissolving Ionic Compounds
-

Ionic compound
water
As more ions are exposed to the water after the
outer ions were carried off, more ions can be
carried off as well.
-
-


-
-
8
Dissolving Ionic Compounds
-

Ionic compound
water













-

These free-floating ions in the solution allow
electricity to be conducted













-







-







-
-


9
Electrolytes
  • When there are free-floating charges in a
    solution then it can conduct electricity.
  • Things that produce free-floating charges when
    dissolved in water are called electrolytes.

10
Dissolving Covalent Compounds
Polar covalent molecules are formed in the same
waywater forms intermolecular forces with the
solute and carries the solute particles away.
11
Dissolving Covalent Compounds
However, the polar covalent molecules stay
together and just separates from other solute
molecules. NO charged ions form.
12
Non-electrolytes
  • When molecules separate from other molecules, but
    free-floating charges are not produced, the
    solution cannot conduct electricity.
  • These are called
  • non-electrolytes

13
Types of Electrolytes
Strong Electrolytes
Non-Electrolytes
Weak Electrolytes
Soluble Ionic compounds Strong Acids Bases
Covalent Compounds except for ACIDS BASES
Insoluble Ionic Compounds Weak Acids Bases
Almost all ions are separated when dissolved in
water.
No molecules separateions are not formed
Only a few ions are separated when dissolved in
water
Does not conduct electricity at all when
dissolved in water
Easily conducts electricity when dissolved in
water
Conducts electricity slightly when dissolved in
water
14
Breaking up Electrolytes
  • Leave polyatomic ions in-tact (including the
    subscript within the polyatomic ion)
  • All subscripts not within a polyatomic ion become
    coefficients
  • Be sure to include charges on the dissociated
    ions!

Example Break up the following ionic compounds
into their ions
KNO3 Ca(NO3)2 Na2CO3
15
Breaking up Electrolytes
  • Leave polyatomic ions in-tact (including the
    subscript within the polyatomic ion)
  • All subscripts not within a polyatomic ion become
    coefficients
  • Be sure to include charges on the dissociated
    ions!

Example Break up the following ionic compounds
into their ions
? K1 NO3-1 ? Ca2 2 NO3-1 ? 2 Na1 CO3-2
KNO3 Ca(NO3)2 Na2CO3
16
Misconceptions about dissolving
  • People often describe something that dissolves as
    having disappeared
  • Before the solute dissolves, its in such a large
    group of particles that we can see it.
  • After dissolving, the solute particles are still
    theretheyre just spread out throughout the
    solution and are in groupings so small that our
    eyes cant see them

17
Types of Solutions
A solution is made of two parts SOLUTE the
substance that is dissolved usually in
minority SOLVENT The substance that does the
dissolving, usually in majority

GAS-LIQUID
SOLID-LIQUID
LIQUID-SOLID
Salt Water
SODA (Carbon dioxide gas in water)
Dental Filling (Mercury in Silver)
When 2 substances dissolve in one another, they
are considered SOLUBLE If they cannot dissolve in
one another, they are INSOLUBLE
18
Types of Solutions

LIQUID-LIQUID
GAS-GAS
SOLID-SOLID
Alcohol water Acetic acid in water(vinegar)
AIR (Oxygen in Nitrogen gas)
ALLOYS (brass, bronze, sterling silver, steel)
When 2 liquids dissolve in one another, they are
considered MISCIBLE If they cannot dissolve in
one another, they are IMMISCIBLE.
19
Types of Solutions
Unsaturated
Super-Saturated
Saturated
Has more solute dissolved than a saturated
solution has at room temperature No visual- need
some background information
Not full- we can add solute to the solvent it
will dissolve Visual-no solid on bottom
Its Full- no more solute can be
dissolved Visual- solid can be seen at the bottom
20
Diagrams of Unsaturated,Saturated,
SuperSaturated Solutions
21
Diagrams of Unsaturated vs Saturated Solutions
22
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23
A SUPERSATURATED SOLUTION
A supersaturated solution can be seeded. This is
a solution at room temperature that has beyond
the maximum amount of solid it can dissolve.
24
A SUPERSATURATED SOLUTION
Crystallization Begins.
25
A SUPERSATURATED SOLUTION
Crystallization Continues.
26
A SUPERSATURATED SOLUTION
A SuperSautrated solution is now saturated. This
is also very exothermic!
27
Solubility of a Gas vs Liquid
  • In general,
  • the higher the temperature of a solution, more
    solid can be dissolved.
  • the higher the temperature of a solution, less
    gas can dissolve. Thermal Pollution!

28
Solubility of Gas vs Liquiud
29
Henrys Law
  • As the pressure above a liquid increases, the
    solubility of a gas within a liquid will increase

30
Reading a Solubility Curve
  • Find the data point on the graph of the
    temperature and solubility of solute in solvent.
  • If it is below the line, it is UNSATURATED
  • IF it is on the line, it is SATURATED
  • If it is above the line, the difference between
    the point and the line is the extra amount that
    is sitting at the bottom.

31
Reading a Solubility Curve
  • Examples
  • What kind of solution occurs when 40g of KCl is
    dissolved in 100 g H2O at 60ºC?
  • What kind of solution occurs when 40g of KCl is
    dissolved in 100 g H2O at 40ºC?
  • What is the maximum amount of NaBr that can be
    dissolved in 100 g H2O at 60ºC?

unsaturated
saturated
120 g
32
Reading a Solubility Curve
  • Examples
  • 4. What is the maximum amount of KNO3 that can be
    dissolved at 70ºC?
  • 5. According to the diamond mark, How much of the
    KNO3 has been added to the water at 70ºC?
  • 6. How much extra KNO3 is sitting at the bottom
    of the container at this temperature of 70ºC?

140g
160g
20g
33
Factors that Affect the Rate of Hydration
  • 1. Temperature
  • 2. Particle Size
  • 3. Agitation (stirring)

34
Section 6.2Concentration
How do we indicate how much of the electrolytes
are in the drink?
35
Concentration
  • A measure of the amount of solute in a given
    amount of solution
  • Qualitative Description
  • Dilute small amount of solute compared to
    solvent
  • Concentrated large amount of solute compared to
    solvent

Concentrated
Dilute
36
Concentrated versus Dilute
solvent
solute
Lower concentration Not as many solute (whats
being dissolved) particles
Higher concentration More solute (whats being
dissolved) particles
37
Molarity a quantitiative description of
concentration
  • Molarity (M) is a concentration unit that uses
    moles of the solute instead of the mass of the
    solute
  • 2M solution is 2 moles of solute dissolved in 1.0
    L of solution

moles
X
Molarity
Liters
38
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39
Molarity Example
Example If you dissolve 5.0 moles of NaCl in
300.0 mL of water, what is the molarity?
40
Molarity Example
Example If you dissolve 5.0 moles of NaCl in
300.0 mL of water, what is the molarity?
Remember to change mL to L! 300. mL of water
0.300 L
17 M NaCl
41
Molarity Example
Example If you dissolve 12 g of NaCl in 150 mL
of water, what is the molarity?
42
Molarity Example
Example If you dissolve 12 g of NaCl in 150 mL
of water, what is the molarity?
1 mole NaCl molecules 58.44 g
12 g NaCl
mole NaCl
1
_______ mole NaCl
0.21
g NaCl
58.44
Remember to change mL to L! 150 mL of water
0.150 L
1.4 M NaCl
43
Molarity Example
Example How many grams of CaCl2 would be needed
to make 25.0 ml of a 2.5M solution?
44
Molarity Example
Example How many grams of CaCl2 would be needed
to make 25.0 ml of a 2.5M solution?
1 mole CaCl2 110.98 g
.063 mol CaCl2
g CaCl2
110.98
6.9 grams CaCl2
CaCl2
1 mol
Remember to change mL to L! 25 mL of water
0.025 L
.0625 moles NaCl
45
How to Make a Solution Make 500.0 ml of a .12
M solution of CoCl2?2H2O
  • 1st Convert your moles of solute to grams.
  • .12 M x .500L .060 moles solute
  • .060 moles x 165.87 g/1mol 9.948 g

  • (10. g)
  • 2nd Add solute amount to a volumetric flask.
  • Add 10.0 g cobalt chloride to flask
  • 3rd Add enough solvent to make the required
    amount of solution and stir.
  • In this case, the solvent is ethanol. Add slowly
    until 500 ml of solution is reached.

46
What Not to Do!
Never add the solvent first!
Never add the solvent first!
47
Dilution A technique used to make a dilute
solution from a Concentrated Solution
.0050 mol .10 L .050 M I2
.0050 mol .50 L .010 M I2
48
How to Calculate a Dilution
  • M1V1 M2V2
  • moles1 moles2
  • M1V1 original (stock) concentration
  • volume
  • M2V2 new concentration volume
  • You do not have to change
    your volume to liters!
  • Example
  • What is the molarity of a new solution if you
    diluted 100.0 ml of 3.0M HCl to 250.0 ml?

49
Example What is the molarity of a new solution
if you diluted 100.0 ml of 3.0 M HCl to 250.0
ml?
  • M1V1 M2V2
  • (3.0M)(100.0ml) (X)(250.0 ml)
  • 300.0 Mml 250.0ml x
  • 250.0 ml 250.0ml
  • X 1.2 M

50
Section 6.3Acidity, pH
How does concentration of acid affect the pH of a
sports drink?
51
Review of Acids Arrhenius Definition
  • Acids produce Hydronium ion (H3O1) in water
  • Hydronium ion is water a hydrogen cation

52
Bases Arrhenius Definition
  • Bases produce the hydroxide ion in water

Hydroxide Ion
53
A new of definition of an ACID According to
Bronsted-Lowry
  • An acid is a hydrogen (proton) donor
  • The substance that remains after the hydrogen has
    been donated is called the conjugate base
  • Example NH3 H2O ? OH- NH4
  • acid conjugate base

54
A new of definition of a BASE According to
Bronsted-Lowry
  • A base is a hydrogen (proton) acceptor
  • The substance that forms after the hydrogen has
    been accepted is called the conjugate acid
  • Example NH3 H2O ? OH- NH4
  • base
    conjugate acid

55
Conjugate Acid-Base Pairs
  • ACIDS BASES WILL ALWAYS BE ON THE REACTANT SIDE
  • CONJUGATE ACIDS BASES WILL ALWAYS BE ON THE
    PRODUCT SIDE
  • Practice Problems Label the acid base on the
    left side of the reaction and the conjugate acid
    conjugate base on the right side.
  • a) HCl H2O ? H3O Cl-
  • ______ ______ ______
    ______
  • b) HCO3-1 H2O ? H2CO3 OH-
  • _____ ______ ______
    ______

acid
base
C.A.
C.B.
acid
base
C.A.
C.B.
56
Characteristics of Acids Bases
Acids
Bases
Produce H3O1 (hydronium ion) in water
Produce OH-1 (hydroxide ion) in water
Tastes sour
Tastes Bitter
Feels slippery
React with active metals to form hydrogen gas
Turns red litmus blue Turns pink in phenlphthalien
Turns blue litmus red Turns clear in
phenolphthalien
React with acids to form salt and water
(neutralization reaction)
React with bases to form salt and water
(neutralization reaction)
Both are considered electrolytes
57
Strength versus Concentration
58
Strong versus Weak Acids
How many hydronium ion anion pairs can you find?
3
How many intact acid molecules can you find?
1
In a Strong acid Most of the acid molecules have
donated the H1 to water
59
Strong versus Weak Acids
How many hydronium ion anion pairs can you find?
1
How many intact acid molecules can you find?
3
In a Weak acid Only a few of the acid molecules
have donated the H1 to water
60
Acids and Bases as Electrolytes
Acids and bases dissociate into ions in water
Free-floating ions in water conduct electricity
Acids Bases are electrolytes
Strong acids and bases are strong
electrolytes Weak acids and bases are weak
electrolytes
61
Calculating pH
62
pH Scale
  • Is a measure the acidity of a sample

less acidic, more basic
more acidic, less basic
Acids have a pH that are less than 7.0 Bases have
pH values that are more than 7.0 Neutral is
considered a pH of 7.0
63
Calculating pH
pH scale Logarithmic scale of the acidity
of a solution
pH has no units
The pH scale uses base 10
The formula for calculating pH The formula for
calculating hydronium ion concentration
concentration in Molarity
64
The - in the pH equation
Because pH is the negative log of concentration
of hydronium, as concentration increases, the pH
goes down.
The lowest pH is the highest concentration of
hydronium ion
65
What does a log scale really mean?
Every change of 1 in pH shows a change of 10x in
concentration of hydronium
pH 4 3 2 1
66
Example
  • The pH of a solution changes from a pH of 5 to a
    pH of 3.
  • Did it increase or decrease in hydrogen ion
    concentration?
  • By what factor did it change?

67
Example 2 Calculating pH
Example Find the pH if the concentration of
H3O1 is 1.0x 10-8 M
68
An example of calculating pH
Example Find the pH if the concentration of
H3O1 is 1.0 x 10-8 M
pH 8.00
69
Example 3 Calculating hydronium concentration
(H3O1)
Example Find the H3O1 if the pH is 5.0
70
An example of calculating hydronium
Example Find the H3O1 if the pH is 5.0
H3O1 1 x 10-5 M
71
Auto-ionization of Water
  • Water molecules collide spontaneously and will
    split into ions. This is called auto-ionization
  • H2O H2O ? H3O1 OH-1
  • At 25C the following is true
  • H3O1 OH-1 1.0 10-14 M2

72
Hydrogen Ion Concentration Values
  • If the hydrogen ion concentration is greater than
    hydroxide ion, the solution is ACIDIC with a pH lt
    7
  • H gt OH- or
  • H gt 1.0 x 10-7 M
  • If the hydrogen ion concentration is less than
    hydroxide ion, the solution is BASIC with a pH gt
    7
  • H lt OH- or
  • H lt 1.0 x 10-7 M
  • If the hydrogen ion concentration is equal to
    hydroxide ion, the solution is NEUTRAL with a pH
    7
  • H OH- 1.0 x 10-7 M

73
Calculating pOH
The formula for calculating pOH The formula
for calculating hydroxide ion concentration To
relate pH and pOH
concentration in Molarity
74
Lets Practice 1
Example Find the pOH if the concentration of
OH-1 is 1.0 10-5 M
75
Lets Practice 1
Example Find the pOH if the concentration of
OH-1 is 1.0 10-5 M
pOH 5.00
76
Lets Practice 2
Example Find the pOH if the pH is 4.
77
Lets Practice 2
Example Find the pOH if the pH is 4.
pOH 10
78
Lets Practice 3
Example Find the OH-1 if the H is 1.0
x10-9M
79
Lets Practice 3 2 ways to do this1st way
Example Find the OH-1 if the H is 1.0 x10-9
OH- 1.0 x10-5 M
80
Lets Practice 3 2 ways to do this2nd way
Example Find the OH-1 if the H is 1.0 x10-9
pH 9.00
pOH 9.00 14 pOH 5.00
OH- 1.0 x10-5 M
81
Lets Practice 4
Example What is the pH if the concentration of
OH- 1.0 x 10-7M
82
Lets Practice 4
Example What is the pH if the concentration of
OH- 1.0 x 10-7
pOH 7
pH 7
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