Transcript Slide 1

Chapter 14
Principles of Neutralization
Titrations
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14A Solutions and indicators for acid/base titrations
 Neutralization titrations are widely used to determine the amounts of acids and
bases and to monitor the progress of reactions that produce or consume
hydrogen ions.
 There are several different types of acid/base titrations:
 Titrating Strong Acids With Strong Bases
 Titrating Strong Bases With Strong Acids
 Titrating Weak Acids With Strong Bases
 Titrating Weak Bases With Strong Acids
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14A-1 Standard Solutions
 The standard reagents used in acid/base titrations are always strong acids or
strong bases, such as HCl, HClO4, H2SO4, NaOH, and KOH.
̶ Weak acids and bases are never used as standard reagents because they
react incompletely with analytes.
 Standard solutions of acids are prepared by diluting concentrated hydrochloric
(HCl), perchloric (HClO4), or sulfuric acid (H2SO4).
̶ Nitric acid (HNO3) is seldom used because its oxidizing properties offer the
potential for undesirable side reactions.
̶ Hot concentrated perchloric and sulfuric acids are potent oxidizing agents
and are very hazardous.
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14A-2 Acid/Base Indicators
An acid/base indicator is a weak organic acid or a weak organic base whose
undissociated form differs in color from its conjugate base or its conjugate acid form.
For example, the behavior of an acid-type indicator, HIn:
HIn + H2O  In- + H3O+
(Acid color)
(base color)
The equilibrium-constant expression for the dissociation of an acid-type indicator
takes the form
[ H 3O  ][ In  ]
Ka 
[ HIn]
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Figure 14-1 Color change and molecular modes for phenolphthalein.
(a) Acidic form after hydrolysis of the lactone form. (b) Basic form.
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The human eye is not very sensitive to color differences in a solution containing a
mixture of HIn and In-, particularly when the ratio [HIn]/[In-] is greater than about 10
or smaller than about 0.1.
HIn, exhibits its pure acid color when
[HIn]/[In-]  10/1
and its base color when
[HIn]/[In-]  1/10
Therefore, the range of hydronium ion concentrations needed for the indicator to
change color can be estimated. For full acid color,
[H3O+] = 10Ka
and for the full base color,
[H3O+] = 0.1Ka
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To obtain the indicator pH range, we take the negative
logarithms of the two expressions:
pH (acid color) = -log(10Ka) = pKa + 1
pH (basic color) = -log(0.1Ka) = pKa – 1
Indicator pH range = pKa  1
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Titration Errors with Acid/Base Indicators
There are two types of titration error in acid/base titrations:
1. Determinate error that occurs when the pH at which the indicator changes color
differs from the pH at the equivalence point.
̶ It can usually be minimized by choosing the indicator carefully or by making
a blank correction.
2. Indeterminate error that originates from the limited ability of the human eye to
distinguish reproducibly the intermediate color of the indicator.
̶ The magnitude of this error depends on (1) the change in pH per milliliter of
reagent at the equivalence point, (2) the concentration of the indicator, and
(3) the sensitivity of the eye to the two indicator colors.
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Variables That Influence the Behavior of Indicators
The pH interval over which a given indicator exhibits
a color change is influenced by (1) temperature, (2) the
ionic strength of the medium, and (3) the presence of
organic solvents and (4) colloidal particles.
̶ Some of these effects can cause the transition
range to shift by one or more pH units.
Figure 14-2 Indicator color as a function of pH (pKa = 5.0).
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The Common Acid/Base Indicators
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14 B Titration of strong acids and bases
The hydronium ions in an aqueous solution of a strong acid have two sources:
(1) the reaction of the acid with water and
(2) the dissociation of water itself.
For a solution of HCl with a concentration greater than about 10-6 M:
[H3O+] = cHCL + [OH-]  cHCL
where [OH-] represents the contribution of hydronium ions from the dissociation of
water.
For a solution of NaOH with a concentration greater than about 10-6 M:
[OH-] = cNAOH + [H3O+]  cNAOH
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pH of Strong Acids and Strong Bases
NaOH and HCl for examples:
a)
b)
NaOH
c)
HCl
High conc. (> 10–6 M):
The pH is controlled by added strong acids
and/or bases.
Low conc. (< 10–8 M):
pH ≈ 7.00, pH controlled by autoprotolysis
of water
Intermediate conc. (10–8~ 10–6 M): pH
obtained by systematic approach
calculations.
Titrating a Strong Acid with a Strong Base
Three types of calculations must be done to construct the hypothetical curve for
titrating a solution of a strong acid with a strong base.
1) Preequivalence: compute the concentration of the acid from its starting
concentration and the amount of base added.
2) Equivalence: the hydronium ion concentration can be calculated directly from the
ion-product constant for water, Kw.
3) Postequivalence: the analytical concentration of the excess base is computed,
and the hydroxide ion concentration is assumed to be equal to or a multiple of
the analytical concentration.
* Convienient way of converting [OH-] to pH
(1) Kw = [H3O+][OH-]
(2) -log Kw = -log [H3O+][OH-] = -log[H3O+] – log[OH-]
(3) pKw = pH + pOH
At 25 oC: 14.00 = pH + pOH
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The Effect of Concentration
Figure 14-3 Titration curves for HCl with NaOH.
(A) Titrating 50.00 mL of 0.0500 M HCl with
0.1000 M NaOH.
(B) Titrating 50.00 mL of 0.000500 mL HCl with
0.00100 M NaOH.
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Choosing an Indicator
Figure 14-3 Titration curves for HCl with NaOH.
(A) Titrating 50.00 mL of 0.0500 M HCl with
0.1000 M NaOH.
(B) Titrating 50.00 mL of 0.000500 mL HCl with0
0.001000 M NaOH.
(1) For titration (A), all three indicators provides a satisfactory end point.
(2) For titration (B), only bromothymol blue provides a satisfactory end point.
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Titrating a Strong Acid with a Strong Base
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Figure 14- 4 Titration curves for NaOH
with HCl.
(A) Titrating 50.00 mL of 0.0500 M NaOH
with 0.1000 M HCl.
(B) Titrating 50.00 mL of 0.00500 mL
NaOH with 0.0100 M NaOH.
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14 C Titration curves for weak acids
Four distinctly different types of calculations are needed to compute values for a
weak acid (or a weak base) titration curve:
1. At the beginning, the solution contains only a weak acid or a weak base, and the
pH is calculated from the concentration of that solute and its dissociation constant.
2. After various increments of titrant have been added (up to, but not including, the
equivalence point), the solution consists of a series of buffers.
- The pH of each buffer can be calculated from the analytical concentrations of the
conjugate base or acid and the concentrations of the weak acid or base that
remains.
3. At the equivalence point, the solution contains only the conjugate of the weak acid
or base being titrated (that is, a salt), and the pH is calculated from the
concentration of this product.
4. Beyond the equivalence point, the excess of strong acid or base titrant suppresses
the acidic or basic character of the reaction product to such an extent that the pH
is governed largely by the concentration of the excess titrant.
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Reviewed
For
HA + H2O
Without
approximation
Approximation
Method 1
Approximation
Method 2
21/177
successive approximation
H3O+ + A–
 K a  K a2  4(K w  K a C HA 
[H 3O ] 
[H 3O+ ]2
Ka 
CHA  [H 3O+ ]
[H 3O+ ]2
Ka 
CHA
Ka K w
)
[H 3O ]
2
[H3O+]2 + Ka [H3O+] – KaCHA = 0
[H3O+ ]  KaCHA
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Half-titration points
The analytical concentrations of acid and conjugate base are identical when an acid
has been half neutralized.
At the half-titration point in a weak-acid titration,
[H3O+] = Ka and pH = pKa
At the half-titration point in a weak-base titration,
[OH-] = Kb, and pOH = pKb
* The buffer capacities of each of the solutions are at a maximum at this point.
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The Effect of Concentration
Figure 14-5 Curve for the titration
of acetic acid with sodium hydroxide.
(A) Titrating 50.00 mL of 0.1000 M HOAC
with 0.1000 M NaOH.
(B) Titrating 50.00 mL of 0.00100 M HOAC
with 0.00100 M NaOH.
The initial pH values are higher and the
equivalence-point pH is lower for the
more dilute solution (Curve B).
At intermediate titrant volumes, however,
the pH values differ only slightly because
of the buffering action of the acetic acid/
sodium acetate system that is present in
this region.
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The Effect of Reaction Completeness
Figure 14-6 The effect of acid
strength (dissociation constant) on
titration curves. Each curve represents
The titration of 50.00 mL of 0.100 M
Weak acid with 0.1000 M strong base.
Titration curves for 0.1000 M
solutions of acids with different
dissociation constants
are shown.
The pH change in the equivalence
-point region becomes smaller as
the acid becomes weaker.
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14D Titration curves for weak bases
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Figure 14-7 Hypothetical titration curves for a series of weak bases of different
strengths.
Each curve represents the titration of 50.00 mL of 0.1000 M base with 0.100 M HCl.
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14 E The composition of solutions during acid/base titrations
Define: cT is the sum of the analytical concentrations of acetic
acid and sodium acetate in a typical buffer solution:
cT  cHOAc  c NaOAc
0
HOAc 


cT
OAc  
1 
cT
therefore,  0  1  1
K a  HOAc 
[OAc ] 
 H 3O  



  K a
H
O
K
HOAc


3

a

cT   HOAc   OAc    HOAc  
  HOAc  (
)


 H 3O 
 H 3O 
Rearranged equation


H
O
 HOAc    3 
cT
 H 3O    K a



H
O
HOAc


3


0 

cT
 H 3O    K a
OAc  
Ka
1 

cT
 H 3O    K a
Figure 14-8 Plots of relative amounts of acetic acid and acetate ion during a
titration.
The straight lines show the change in relative amounts of HOAc (α0) and OAc2
(α 1) during the titration of 50.00 mL of 0.1000 M acetic acid.
The curved line is the titration curve for the system.
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End of Chapter 14