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Titration:W eak Acid by Strong B ase 0 2 4 6 8 10 12 14 0 0.05 0.1 0.15 0.2 0.25 Volum e ofB ase pH HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

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Page 1: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Titration: Weak Acid by Strong Base

0

2

4

6

8

10

12

14

0 0.05 0.1 0.15 0.2 0.25

Volume of Base

pH

HARRIS’s Ch. 10-12

Supplement

Zumdahl’s

Chapter 15

Page 2: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Supplementary Content

Harris Chapter 10 Buffer Capacity, Ionic Strength and

Henderson–Hasselbalch

Harris Chapter 11 Diprotics

Intermediate form Buffers Fractional Composition

Harris Chapter 12 Titration accuracy limit Diprotic titration Indicated indicators Spreadsheet Titration

Curves Monoprotic Diprotic Triprotic

Page 3: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Buffer Capacity,

Buffers resist pH change only while both forms present in significant quantity.

We want slope of pH with Cbase to be low!

Alternately, dCb/dpH should be high and represents , the capacity to resist.

= (ln 10) SA / (S+A) while H–H viable. Limits: min=2.303 [smaller], max=1.152 [S=A]

Page 4: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Henderson–Hasselbalch

pH = pKa + log( aS / aA ) pKa + log([S]/[A])

aY = Y [Y] = thermodynamic “activity” Y = “activity coefficient,” a correction factor,

well known for dilute ionic solutions. (Ch. 8)

For Yz±, ion of radius (pm) in a solution of many ions and = ½ ci zi

2 is ionic strength, log Y = – 0.51z2 ½ / [ 1 + ( ½ / 305) ]

Page 5: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Diprotic Intermediate Form

H2A HA– + H+ (abbreviated below as A B + H)

HA– A2– + H+ (abbreviated below as B C + H) HA– is the intermediate (amphiprotic) form.

HA– dominates at 1st equivalence point, where ~ zero! World’s worst buffer.

Also, near equivalence, Kw is important (to all

conjugates), and must be included. How?

Page 6: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Explicit Water Equilibrium

If both H+ and OH– are important, they must be included in MHA’s charge balance: [H+] + [M+] = [HA–] + 2[A2–] + [OH–] or H + F H + (A + B + C) = B + 2C + Kw/H

H = C – A + Kw/H = K2B/H – HB/K1 + Kw/H

H2 = K2B – H2B/K1 + Kw

H2 (B/K1 + 1) = K2B + Kw

Page 7: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Solution from B = HA–

H = [ (K1 K2 B + K1 Kw) / (B + K2) ] ½

But if weak [B]0 = F, then Beq F >> K2

H [ (K1 K2 F + K1 Kw) / F ] ½

And if Kw << F K2

H ~ [ K1 K2 F / F ] ½ = (K1 K2) ½

pH ~ ½ (pK1 + pK2)Like pH = pKa at V½ for monoprotic titration.

Page 8: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Diprotic Buffer Solutions

Both Henderson–Hasselbalch eqns apply! pH = pK1 + log( [HA–] / [H2A] )

pH = pK2 + log( [A2–] / [HA–] ) same pH!

Make buffer of A & B or B & C, using the appropriate pK; the other H–H equation then governs the third species (not added).

What if we add amounts of A, B, and C?

Page 9: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Fractional Composition,

For monoprotic, (A–) = % diss. / 100% (wow)

Since [HA] = [H+][A–]/Ka = [H+](F–[HA])/Ka,

[HA] = [H+] F / ( [H+] + Ka )

HA = [HA] / F = [H+] / ( [H+] + Ka ) A¯ = 1 – HA = Ka / ( [H+] + Ka )

For diprotic, (H2A) + (HA–) + (A2–) = 1 and after we agonize over mass balance,

Page 10: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Diprotic Fractional Composition

H2A = [H+]2 / D

HA¯ = K1 [H+] / D

A²¯ = K1 K2 / D

D = [H+]2 + K1 [H+] + K1 K2

gives the max HA¯ where [H+] = (K1K2)½ and its max value is K1

½ / (K1½ + 2 K2

½)

Page 11: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Titration Accuracy Limits

Besides indicators and eyeballs, endpoint accuracy depends upon high sensitivity of pH to Vtitrant. Here are things to avoid: Very weak acids have low pH sensitivity there. Very dilute solutions are similarly insensitive. Very strong analytes may be sensitive but imply

refilling burettes, increasing reading errors.

Page 12: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Diprotic Titrations

Deal with two buffer regions and equivalence points associated with the Ka1 and Ka2. While buffer formulae (H–H) are identical,

equivalence point formulae are not. pHeq2 14 + ½ log[ F Kw/Ka2 ] (same as monoprotic)

pHeq1 ½ ( pKa1 + pKa2 )Assuming the curve shows clear equivalence points.

Page 13: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Choosing Indicators

Paradoxical as it may seem, the proper indicator has its best buffer region, pH = pKi

where the analyte has its equivalence point, e.g. pH 14 + ½ log( F Kw / Ka ). At such a pH, the indicator has equal amounts of

acid and conjugate base where the analyte has pure conjugate.

Page 14: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Spreadsheet Titration Curves

Assume Ca and Cb known; plot Vb vs. pH.Because it’s easier than pH vs. Vb!

[H+] + [Na+] = [A –] + [OH –] [Na+] = Cb Vb / Vtotal = Cb Vb / ( Va + Vb )

[A –] = A¯ Fa = A¯ Ca Va / ( Va + Vb )

Cb Vb / ( Ca Va ) = {A¯ – ([H+]–[OH–])/Ca} / {1+([H+]–[OH–])/Cb}

Page 15: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

Only Somewhat Twisted

= {A¯ – ([H+]–[OH–])/Ca} / {1+([H+]–[OH–])/Cb}All known if pH is known.

A¯ = Ka / ( [H+] + Ka )

[OH –] = Kw / [H+]

Therefore Vb = Ca Va / Cb

as a function of pH. Excel doesn’t care which is the X or Y axis.

Page 16: HARRIS’s Ch. 10-12 Supplement Zumdahl’s Chapter 15

“To Diprotica and Beyond”

For weak polyprotic acids and strong bases: X = 1 – ( [H+] – [OH –] ) / Ca

Xm = {A¯ – ([H+]–[OH–])/Ca}

Xd = {HA¯ + 2A²¯ – ([H+]–[OH–])/Ca}

Xt = {H2A¯ +2HA²¯ +3A³¯ – ([H+]–[OH–])/Ca}

D for triprotic fractional compositions: D = [H+]³ + K1[H+]² + K1K2[H+] + K1K2K3