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Buffers

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Buffers Buffers are composed of a weak acid and its salt or a weak base and its salt. HA A- + H+ This weak ionization has HA available to react with added base ... – PowerPoint PPT presentation

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Title: Buffers


1
Buffers
  • Buffers are composed of a weak acid and its salt
    or a weak base and its salt.
  • HA ltgt A- H
  • This weak ionization has HA available to react
    with added base or A- to react with acid which
    leaves H relatively constant in either case.

2
Buffers
  • Examples of preparation and use of buffers.
  • Example 1 Using Glycine
  • Example 2 Using phosphate
  • Example 3 Resistance to acid or base
  • Example 4 Glucose-6-phosphate

3
Example 1, Glycine Buffer
  • Prepare 500 ml of 0.2 M glycine buffer at pH 9.2
    from crystalline zwitterionic glycine,
  • NH3CH2COO-, and 1 M NaOH.
  • Glycine pKas are 2.4 and 9.8 and it has a
    molecular weight of 75 gm/mol.

4
Titration curve for Ala
5
Equilibrium involved
  • Since the second pKa is within one pH unit of the
    desired buffer pH (9.2), the ionization
    involved in this buffer is
  • NH3CH2COO- ----gt NH2CH2COO- H
  • conj. acid (HA) conj. base (A-)
  • pKa 9.8

6
Total amount of Glycine needed
  • Total mmol glycine needed
  • (500 ml)(0.2 mmol/ml) 100 mmol
  • Total grams of glycine needed
  • (75 mg/mmol)(100 mmol) 7500 mg 7.5 gram
    (Note this is all HA)
  • If the mmol of each HA and A- are known then one
    can determine the volume of 1 M NaOH needed to
    convert part of the initial 100 mmol of glycine
    (HA) to its conj. base.

7
Amounts of HA and A- needed
  • The amounts of the conj. acid and conj. base
    needed are obtained using the Henderson-Hasselbalc
    h equation.
  • The Henderson-Hasselbalch Equation
  • pH pKa log (A-) / (HA)
  • 9.2 9.8 log (A-) / (HA)
  • Solving this gives (A-)/(HA) 0.25

8
Amounts of HA and A-
  • Since the ratio of (A-)/(HA) 0.25
  • The fraction of total glycine as
  • A- (0.25/1.25) 0.20 and
  • HA (1.0/1.25) 0.80
  • So, the mmol of A- 0.2 (100mmol) 20 mmol
  • and the mmol of HA 0.80 (100mmol) 80 mmol

9
Amount of NaOH needed
  • Therefore, 20 mmol of 1 M NaOH are needed to
    convert 20 mmol of HA to A-.
  • Volume of base needed is
    mmol (ml)(M)
  • 20 mmol ml base (1 mmol/ml)
  • ml base 20 ml

10
Example 1Buffer Preparation
  • To prepare this buffer one would weigh out 7.5 gm
    of glycine, transfer it to a 500 ml volumetric
    flask and dissolve it in some water. Then add 20
    ml of 1 M NaOH, fill to the mark with water and
    mix.

11
Example 2, Phosphate Buffer
  • Prepare 250 ml of 0.2 M phosphate buffer at pH
    6.93.
  • Available are 2.8 M H3PO4 (phosphoric acid) and
    crystalline Na2HPO4 (MW 142 gm/mol).
  • Phosphate pKas are 2.1, 6.8 and 12.3.

12
Equilibrium involved
  • Which phosphate equilibrium is involved here?
  • Since the second pKa is within one pH unit of the
    desired buffer pH (6.93), the ionization
    involved in this buffer is
  • H2PO4- ----gt HPO4 H pKa 6.8
    conj. acid (HA) conj. base (A-)

13
Total amount of Phosphate needed
  • Total mmol phosphate needed (250 ml)(0.2
    mmol/ml) 50 mmol
  • (Which is the sum of H2PO4- and HPO4)
  • If the mmol of each HA and A- are known then one
    can determine the volume of 2.8 M H3PO4 needed
    and the weight of Na2HPO4 needed to prepare the
    buffer.
  • Use the Henderson-Hasselbalch equation to do this.

14
Amounts of HA and A- needed
  • pH pKa log (A-) / (HA)
  • 6.93 6.8 log (A-) / (HA)
  • and solving this gives (A-) /(HA) 1.349
  • The fraction of A- is (1.349/2.349 0.574
  • and the fraction as HA is (1.0/2.349) 0.426
  • So, the mmol of A- 0.574 (50mmol) 28.7mmol
  • The mmol of HA 0.426 (50mmol) 21.3 mmol

15
Producing HA
  • A- (HPO4) is available as Na2HPO4 but HA
    (H2PO4-) must be made by the equation below
  • H3PO4 Na2HPO4 -----gt 2 NaH2PO4
  • This is due to the fact that H3PO4 is the only
    other starting material for the buffer.

16
Amount of Na2HPO4 needed
  • The 21.3 mmol of HA needed are obtained by
    combining 10.65 mmol of H3PO4 and 10.65 mmol of
    Na2HPO4.
  • H3PO4 Na2HPO4 -----gt 2 NaH2PO4
  • 10.65 10.65 21.3
  • In addition, another 28.7 mmol of Na2HPO4 are
    needed to provide A-.
  • Total mmol Na2HPO4 required 10.65 28.7
    39.35 mmol.

17
Amount of H3PO4 needed
  • Total grams of Na2HPO4 required
  • 39.35 mmol (142 mg/mmol) 5587.7 mg
    5.588 gm
  • The volume of H3PO4 needed
  • 10.65 mmol ml H3PO4 (2.8 mmol/ml)
  • so the ml of H3PO4 3.80 ml.

18
Example 2Buffer Preparation
  • To prepare this buffer one would weigh out 5.588
    gm of Na2HPO4, transfer it to a 250 ml volumetric
    flask and dissolve it in some water.
  • Then add 3.80 ml of 2.8 M H3PO4, fill to the mark
    with water and mix.

19
Example 3, Effect of NaOH on the Glycine Buffer
  • In example 1, 500 ml of pH 9.2 glycine buffer was
    prepared.
  • If 5 ml of 1 M NaOH are added to this buffer,
    what will be the new pH ?
  • How much of a change in pH does this represent ?

20
Example 3, Effect of NaOH on the Glycine Buffer
  • Five ml of 1 M NaOH (5 ml)(1M) 5 mmol NaOH
  • NaOH NH3CH2COO- ----gt NH2CH2COO- H2O
  • Initial (HA) 80 mmol (A-) 20 mmol
  • Final (HA) 75 mmol (A-) 25 mmol
  • pH pKa log (A-) / (HA)
  • pH 9.8 log (25/505) / (75/505) 9.8 -
    0.5
  • pH 9.3 (A change of 0.1 pH unit.)

21
Example 4
  • Glucose-6-phosphate
  • Glucose-6-phosphate exhibits two ionizations
  • Glucose-6-OPO3H2 lt gt Glucose-6-OPO3H- H
    pK1 0.94
  • Glucose-6-OPO3H- lt gt Glucose-6-OPO3 H pK2
    6.11
  • 1. Which equilibrium predominates at pH 7.1 ?

The second equilibrium (pK2).
22
Example 4
  • Glucose-6-phosphate
  • 2. What fraction of each of the forms in the
    second equilibrium exist at pH 7.1 ?
  • pH pKa log (A-) / (HA)
  • 7.1 6.11 log (A-) / (HA)
  • Solving this gives (A-)/(HA) 9.75

So, the fraction of A- 9.75/10.75 0.91 and
the fraction of HA 1/10.75 0.09.
23
End of Buffers
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