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Buffers

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Buffers Buffered solutions A solution that resists a change in pH. Buffers are: A solution that contains a weak acid-weak base conjugate pair. Often prepared by ... – PowerPoint PPT presentation

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Title: Buffers


1
Chapter 17
  • Buffers

2
Buffered solutions
  • A solution that resists a change in pH.
  • Buffers are
  • A solution that contains a weak acid-weak base
    conjugate pair.
  • Often prepared by mixing a weak acid, or a weak
    base, with a salt of that acid or base.

3
Buffered solutions
  • The solution has the ability to resist changes in
    pH upon the addition of small amounts of either
    acid or base.
  • We can make a buffer of any pH by varying the
    concentrations of these solutions.

4
What is the pH of a buffer that is 0.12M in
lactic acid, HC3H5O3 , and 0.10M in sodium
lactate? For lactic acid, K 1.4 x 10 -4
HC3H5O3 ? H
C3H5O3-1
I 0.12 M 0 0.10 M
C -x x x
E 0.12 x x 0.10 x
5
  • H 1 C3H5O3-1
  • Ka HC3H5O3
  • 1.4 x 10-4 (x) (0.10 x)
  • (0.12 x)
  • Because of the small Ka and the presence of the
    common ion, it is expected that x will be small
    relative to 0.12 or 0.10M.
  • x 1.7 x 10 -4 M therefore H1 1.7 x 10
    -4 M
  • pH -log (1.7 x 10 -4 M) 3.77

6
Use Henderson-Hasselbach Instead
  • base
  • pH pKa log acid
  • 0.10
  • pH -log (1.4 x 10-4) log 0.12
  • pH 3.85 (-0.08) 3.77

7
Practice Problem
  • Calculate the pH of a buffer composed of 0.12M
    benzoic acid (HC7H5O2)and 0.20M sodium benzoate.
    Ka 6.3 x 10-5
  • ans 4.42
  • Remember the Aqueous Equilibrium Constants are
    located in Appendix D of your textbook.

8
Buffered Solutions
  • Buffers resist changes in pH because they contain
    both an acidic species to neutralize OH-1 ions
    and a basic one to neutralize H1 ions.
  • It is important that the acidic and basic species
    of the buffer do not consume each other through a
    neutralization reaction.

9
Buffered Solutions
  • HA H A-
  • Ka H A- HA
  • Buffers most effectively resist a change in pH in
    either direction when the concentrations of HA
    and A- are about the same. When HA equals A-
    then H equals Ka.
  • Scientists usually try to select a buffer whose
    acid form has a pKa close to the desired pH.

10
General equation
  • Ka H A- HA
  • so H Ka HA A-
  • The H depends on the ratio HA/A-
  • Take the negative log of both sides
  • pH -log(Ka HA/A-)
  • pH -log(Ka)-log(HA/A-)
  • pH pKa log(A-/HA)

11
This is called the Henderson-Hasselbach equation
  • pH pKa log(A-/HA)
  • pH pKa log(base/acid)

12
Try an Acid
  • Calculate the pH of the following mixture
  • Prob. 1
  • 0.75 M lactic acid (HC3H5O3) and 0.25 M sodium
    lactate (Ka 1.4 x 10-4)
  • Answer
  • pH -log(1.4x10-4) log0.25/0.75
  • pH 3.38

13
Now Try a Base
  • Calculate the pH of the following mixture
  • 0.25 M NH3 and 0.40 M NH4Cl
  • (Kb 1.8 x 10-5)
  • Answer
  • NH3 NH41 OH-1
  • (NH3 is B, NH41 is HB1)
  • pOH pKb log HB1 / B
  • pOH -log(1.8x10-5) log0.4/0.25
  • pOH 4.94 now convert to pH

14
Buffering Capacity
  • This is the amount of acid or base the buffer can
    neutralize before the pH begins to change to an
    appreciable degree.

15
Buffering Capacity
  • The buffering capacity, that is, the
    effectiveness of the buffer solution, depends on
    the amount of acid and conjugate base from which
    the buffer is made.
  • The larger the amount the greater the buffering
    capacity.
  • In general, a buffer system can be represented as
    salt-acid or conjugate base-acid.

16
Buffer capacity
  • The pH of a buffered solution is determined by
    the ratio A-/HA.
  • As long as this doesnt change much the pH wont
    change much.
  • The more concentrated these two are the more H
    and OH- the solution will be able to absorb.
  • Larger concentrations means bigger buffer
    capacity.

17
Buffer Capacity
  • Calculate the change in pH that occurs when 0.010
    mol of HCl(g) is added to 1.0L of each of the
    following
  • 5.00 M HAc and 5.00 M NaAc
  • 0.050 M HAc and 0.050 M NaAc
  • Ka 1.8x10-5

18
Buffer capacity
  • The best buffers have a ratio A-/HA 1
  • This is most resistant to change
  • True when A- HA
  • Make pH pKa (since log10)

19
Addition of Strong Acids or Bases to Buffers
  • See pg. 648 BL for explanation and examples.

20
Adding a strong acid or base
  • Do the stoichiometry first.
  • A strong base will take protons from the weak
    acid reducing HA0
  • A strong acid will add its proton to the anion of
    the salt reducing A-0
  • Then do the equilibrium problem.

21
B L pg 649
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25
  • Try the Buffer worksheet from the Chang
    chemistry text.

26
Prove theyre buffers
  • What would the pH be if 0.020 mol of HCl is added
    to 1.0 L of both of the preceding solutions.
  • What would the pH be if 0.050 mol of solid NaOH
    is added to each of the proceeding.

27
  • Thanks to Mr. Green
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