Transcript Chapter 21 - Neutralization
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Chapter 19 - Neutralization
Section 19.1
Neutralization Reactions 2 OBJECTIVES: Explain how acid-base titration is used to calculate the concentration of an acid or a base
Section 19.1
Neutralization Reactions 3 OBJECTIVES: Explain the concept of equivalence in neutralization reactions.
Acid-Base Reactions Acid + Base Water + Salt Properties related to every day: antacids depend on neutralization farmers use it to control soil pH formation of cave stalactites human body kidney stones 4
Acid-Base Reactions Neutralization Reaction - a reaction in which an acid and a base react in an aqueous solution to produce a salt and water: HCl
(aq)
H
2
SO
4(aq)
+ NaOH
(aq)
+ 2KOH
(aq)
NaCl
(aq)
+ H
2
O
(l)
K
2
SO
4(aq)
+ 2 H
2
O
(l)
5 Table 19.1, page 458 lists some salts
Titration Titration is the process of adding a known amount of solution of known concentration to determine the concentration of another solution Remember? - a balanced equation is a mole ratio Sample Problem 19-1, page 460 6
Titration The concentration of acid (or base) in solution can be determined by performing a neutralization reaction An indicator is used to show when neutralization has occurred Often use phenolphthalein- colorless in neutral and acid; turns pink in base 7 Simulation Simulation Worksheet
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Steps - Neutralization reaction 1. A measured volume of acid of unknown concentration is added to a flask 2. Several drops of indicator added 3. A base of known concentration is slowly added, until the indicator changes color-measure the volume Figure 19.4, page 461
Neutralization The solution of known concentration is called the standard solution added by using a buret Continue adding until the indicator changes color called the “end point” of the titration Sample Problem 19-2, page 461 10
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Equivalents One mole of hydrogen ions reacts with one mole of hydroxide ions does not mean that 1 mol of any acid will neutralize 1 mol of any base because some acids and bases can produce more than 1 mole of hydrogen or hydroxide ions 13 example: H
2
SO
4(aq)
2H
+
+ SO
4 2-
Equivalents Made simpler by the existence of a unit called an equivalent One equivalent (equiv) is the amount of acid (or base) that will give 1 mol of hydrogen (or hydroxide) ions 1 mol HCl = 1 equiv HCl 1 mol H
2
SO
4
= 2 equiv H
2
SO
4
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Equivalents In any neutralization reaction, the equivalents of acid must equal the equivalents of base How many equivalents of base are in 2 mol Ca(OH)
2
?
The mass of one equivalent is it’s gram equivalent mass (will be less than or equal to the formula mass): HCl = 36.5 g/mol; H
2
SO
4
= 49.0 g/mol
Equivalents Sample Problem 19-3, page 462 Sample Problem 19-4, page 462 16
Normality (N) Useful to know the Molarity of acids and bases Often more useful to know how many equivalents of acid or base a solution contains Normality (N) of a solution is the concentration expressed as number of equivalents per Liter 17
Normality (N) Normality (N) = equiv/L equiv = Volume(L) x N; and also know: N=M x eq; M = N / eq Sample Problem 21-5, page 621 Diluting solutions of known Normality: N
1
x V
1
= N
2
x V
2
N
1
and V
1
are initial solutions N
2
18 and V
2
are final solutions
Normality (N) Titration calculations often done more easily using normality instead of molarity In a titration, the point of neutralization is called the equivalence point the number of equivalents of acid and base are equal 19
Normality (N) Doing titrations with normality use: N
A
x V
A
= N
B
x V
B
Sample Problem 19-6, page 464 Sample Problem 19-7, page 464 Sample Problem 19-8, page 464 20
Section 19.2 Salts in Solution OBJECTIVES: Demonstrate with equations how buffers resist changes in pH 21
Section 19.2 Salts in Solution OBJECTIVES: Calculate the solubility product constant (K
sp
) of a slightly soluble salt 22
Salt Hydrolysis A salt: comes from the anion of an acid (Cl -) comes from the cation of a base (Na +) formed from a neutralization reaction some neutral; others acidic or basic Salt hydrolysis- salt reacts with water to produce acid or base solution 23
Salt Hydrolysis Hydrolyzing salts usually made from: strong acid + weak base, or weak acid + strong base Strong refers to the degree of ionization (100%) What pH will result from the above combinations?
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Salt Hydrolysis To see if the resulting salt is acidic or basic, check the “parent” acid and base that formed it: NaCl HCl + NaOH NH 4 OH H
2
SO
4
+ NH
4
OH CH 3 COOK CH
3
COOH + KOH 25
Strong Acids HCl HClO
4
H
2
SO
4
HI HNO
3
HBr
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Strong Bases Mg(OH)
2
NaOH Ca(OH)
2
KOH
To determine if a salt is made From a combination which is: acid/base weak/weak weak/strong strong/strong strong/weak
Na Cl
OH H
27 Lab 42 : Salt Hydrolysis Universal Indicator Colors
Buffers Buffers are solutions in which the pH remains relatively constant when small amounts of acid or base are added made from a pair of chemicals a weak acid and one of it’s salts; HA / A or a weak base and one of it’s salts NH 3 / NH 4 + 28 Simulation
Buffers A buffer system is better able to resist changes in pH than pure water 29 Since it is a pair of chemicals: one chemical neutralizes any acid added, while the other chemical would neutralize any additional base they make each other in the process!
pH Unbuffered reaction between and acid an base HCl + NaOH NaCl + HOH pH Buffered solution and reaction of an acid with a base HA / A HCl + A HA + Cl 30 Add strong acid Add strong acid
Buffers Example: Ethanoic (acetic) acid and sodium ethanoate (also called sodium acetate) HC 2 H 3 0 2 / NaC 2 H 3 0 2 becomes HC 2 H 3 0 2 / C 2 H 3 0 2 1 Weak acid weak base 31 The buffer capacity is the amount of acid or base that can be added before a significant change in pH
1.
Buffers Buffers that are crucial to maintain the pH of human blood: carbonic acid - hydrogen carbonate H 2 CO 3 / HCO 3 2. dihydrogen phosphate - monohydrogen phoshate H 2 PO 4 / HPO 4 2 Table 19.2, page 469 has some important buffer systems Sample Problem 19-9, page 468 32
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Calculating k
sp
or Solubility Product Constant
Copy Example 10/11 pg 470/471 into your notes What does a high Ksp mean?
What does a low Ksp mean?
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Solubility Product Constant Salts differ in their solubilities Table 19.3, page 470 Most “insoluble” salts will actually dissolve to some extent in water said to be slightly, or sparingly, soluble in water 35
Solubility Product Constant Consider: AgCl
(s)
Ag
+ (aq)
+ Cl
-
The “equilibrium expression” is:
(aq)
[ Ag
+
] x [ Cl
-
] K
eq
= [ AgCl ] 36
Solubility Product Constant But, the [ AgCl ] is constant as long as some undissolved solid is present Thus, a new constant is developed, and is called the “solubility product constant” (K
sp
): K
eq
x [ AgCl ] = [ Ag
+
] x [ Cl
-
] = K
sp
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Solubility Product Constant Values of solubility product constants are given for some sparingly soluble salts in Table 19.4, page 471 Although most compounds of Ba are toxic, BaSO
4
is so insoluble that it is used in gastrointestinal examinations by doctors! - p.632
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Solubility Product Constant To solve problems: a) write equation, b) write expression, and c) fill in values using x for unknowns Sample Problem 21-10, page 634 Sample Problem 21-11, page 634 39
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Common Ion Effect A “common ion” is an ion that is common to both salts in solution example: You have a solution of lead (II) chromate. You now add some lead (II) nitrate to the solution.
The lead (II) ion is the common ion 41
PbCrO
4
Pb
2+
+ CrO
4 2-
Add
Pb
(NO
3
)
2 This causes a shift in equilibrium (due to Le Chatelier’s principle), and is called the common ion effect 42
PbCrO
4 shift Pb 2+
+ CrO
4 2-
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Common Ion Effect Sample Problem The Ksp of silver iodide is 8.3x10
-17 . What is the iodide concentration mol of Ag NO 3 of a 1.00L saturated solution of is added?
Ag I to which 0.020 1. Write the equilibrium equation.
Note: X is AgI (s) Ag 1+ 2. Write the Ksp expression + I 1 Ksp Ksp = [Ag 1+ ] 1 = ( x ) 1 [ I 1 ] 1 = 8.3x10
-17 ( x ) 1 = 8.3x10
-17 So small that it can be ignored Ksp = ( x Ksp = + 0.020) 1 ( x ) 1 (0.020) ( x = 8.3x10
-17 ) = 8.3x10
-17 44 x = 4.2x10
-15 The [ ] of iodide ion is 4.2x10
-15 M
The solubility product constant (K will form or not in a reaction
sp
) can be used to predict whether a precipitate if the calculated ion-product concentration is greater than the known K
sp
, a precipitate will form 45
ksp Sample Problem: A student prepares a solution by combining 0.025 mol CaCl 2 with 0.015 mol Pb(NO 3 ) 2 in a 1 L container. Will a precipitate form?
WHAT WE KNOW!!!
Ca Cl 2 0.025 mol/L + Pb (NO 3 ) 2 0.015 mol/L Ca(NO 3 ) 2 (aq) +
PbCl 2 (s)
X ppt 46
PbCl
2
Pb
2+
+ 2 Cl ksp = [Pb
2+
]
1
[Cl
1-
]
2 The values we need to solve the problem! 1-
1) Calculate the concentration of the ion’s used to make the precipitate.
CaCl 2 0.025 mol/L Ca 2+ + 2 Cl 0.025 mol CaCl 1L 2 2 mol Cl 1 mol CaCl 2 0.050 mol Cl L Pb 2+ + 2NO 3 Pb(NO 3 ) 2 0.015 mol/L 0.015 mol Pb(NO 3 ) 2 1L 47 1 mol Pb2+ 1 mol Pb(NO 3 ) 2 0.015 mol Pb 1L 2+
2) Calculate the Ksp for the precipitate PbCl 2 Pb 2+ + 2 Cl Ksp = [ Pb 2+ ] 1 [ Cl ] 2 Ksp = ( 0.015 M ) 1 ( 0.050 M ) 2 Ksp for PbCl 2 = 3.75 x 10 -5 Calculated Ksp 3.75 x 10 -5 is > Known Ksp 1.7 x 10 -5 for PbCl 2 See pg 471 Table 19-4 for known values 48 Calc > Known = PPT Known> Calc = No PPT Known = Calc = No PPT
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