Acid – Base Titrations
Pabitra Kumar Mani ,
Assoc. Professor, ACSS,
BCKV
Bronsted-Lowry acid-base theory- An acid is a proton donor and a base is a proton acceptor
The Bronsted-Lowry theory concentrates on proton donation and acceptance.
•water molecules undergoing dissociation or self-ionisation because of the reaction 2H2O(l) ⇋ [H3O
+(aq)] + [OH-
(aq)] BUT, in this reaction, water acts as both acid and baseTherefore water is an amphoteric oxide
•e.g. water acting as a base - proton acceptor with a stronger acid like the hydrogen chloride gas
HCl(g) + H2O(l) ⇋ H3O+
(aq) + Cl-(aq)
This is how hydrochloric acid is formed which you write simply as HCl. e.g. water acting as an acid - proton donor with a weak BUT stronger base like ammonia gas
NH3(aq) + H2O(l) ⇋ NH4+
(aq) + OH-(aq)
This is why ammonium solution is alkaline - sometimes wrongly called 'ammonium hydroxide' instead of aqueous ammonia
Lewis acid-base electron pair theory : Acid is an electron pair acceptor but base is an electron pair donor. e.g. a non B-L, but a Lewis acid-base interaction is boron trifluoride (Lewis-acid, electron pair acceptor) reacting with ammonia (Lewis-base, electron pair donor).
F3B + :NH3 ⇋ F3B-NH3 Acid base
Note: In organic chemistry mechanisms, nucleophiles are Lewis bases and electrophiles are Lewis acids and they may fit into the Bronsted-Lowry definition too e.g. protonation of alcohols and alkenes via acid.
In Transition Metal chemistry, ligands like water, can donate a pair of non-bonding electrons (lone pair) into a vacant orbital of a central metal ion and so dative covalent (co-ordinate) bonds hold a complex together.
The central metal ion with vacant bonding orbitals can act as a Lewis acid by accepting an electron pair to form a dative covalent bond. Ligands act as Lewis bases by electron pair donation to form the metal-ligand co-ordinate bond
HCl gas: HCl(g) + H2O(l) ⇋ H3O+(aq) + Cl-
(aq) acid base conjugate acid. conjugate base.
The resulting solution is called hydrochloric acid
Ammonia: NH3(aq) + H2O(l) ⇋ NH4+
(aq) + OH-(aq)
base acid conjugate acid conjugate base
HCO3-, can act as an acid with a base or act as a base with an acid, such
behaviour is described as amphoteric.
HCO3- + H3O+
(aq) ==> 2H2O(l) + CO2(aq) HCO3
- acting as a base, accepting a proton from an acid.
HCO3- + OH-
(aq) ==> H2O(l) + CO32-
(aq) HCO3
- acting as an acid, donating a proton to the hydroxide ion base.
Volumetric analysis (Titrimetry)(i) Acid-Base and (ii) Displacement titrimetryTitrant: the reagent of known concn, Titrand: the substance being titrated H+ + OH- = H2O.......neutralisation rn Acid base MX + HA ⇋ HX + MA Salt Acid1 Acid2 Salt (acid2 weak than acid1)
MX + BOH ⇋ BX + MOH base1 base2 (base2 weaker tahn base1)
Primary standard..... (It must be easy to obtain, to purify, to dry and to preserve in pure state)
H2C2O4.2H2O (Crystalline) primary std acids and reductant, Na2CO3(anhy), KH(IO3), Phthalate, Borax (Na2B4O7.10H2O), Potassium tetra borate , 36.39% H2SO4 –non-hygroscopic used a s primary std.Constant boiling HCl can be used to prepare standard HCl solnBenzoic acid –primary standardSecondary standard..... NaOH,HCl, H2SO4, CuSO4.5H2O
Equivalence point is determined by using an indicator (W.Ostald) (pH-indicator)
HIn H⇋ + + In- HIn and In- are differently coloured
Acidic ionic formIndicator(mol.form)
InOH ⇋ In+ + OH- InOH and In+ are differently coloured Basic ionic formIndicator(mol.form)
HIn ⇋ Hin* ⇋ H+ + In-
HIn and In- are differently colouredTautomeric transformation
HIn H⇋ + + In-
kIn-a = HIn
InH
In
HIn kIn-a
=[H+]
pH = - log - logkIn-a
In
HIn
= pKIn-a + log HIn
In
pHAlkaline colour intensity
acidic colour intensity
HIn
In
When = 10, pH= pKIn-a
+ 1
and When = 1/10, pH= pK In-a
- 1 HIn
In
Operationally, pH= pKIn-a
± 1
In 10 times concn of HIn i.e., when the color due to is dominant In
During titration, if pH at equivalence point, lies in the range pKIn-a
± 1,
that indicator can be used to detect the e.p. In the particular titration
InOH ⇋ In+ + OH-
KIn-b = InOH
OHIn
=[OH-] kIn-b In
InOH
-log[OH-] or, pOH = pKIn-b + log10
InOH
In pH + pOH =pKw=14
pH = 14 - pKIn-b -log10
InOH
InpH -14 = - pOH
pH = pKIn-a -log10
InOH
In
HA ⇋ H+ + A-
pKa+pKb= pKw
Indicator pH range ColourAcid
Change Alkaline
pKIn-a
Bromophenol Blue
2.8-4.6 yellow blue 4.0
Methyl orange 3.1-4.4 O Y 3.7
Methyl red 4.2-6.3 R Y 5.1Bromothymol Blue
6.0-7.6 Y Blue 7.0
Phenolphthalein 8.3-10.0 COLOURLESS
R 9.6
Thymolphthalein 8.3-10.5 C blue 9.2
1. Strong acid –strong base titrations
1(N) HCl ------- 1(N) NaOH
110 [OH-]= 10/210 12.7
150 [OH-]= 50/250 13.3
ml of alkaliadded
[H+] g-ion/L pH
0 1 0
50 (50x 1/150)x 1 0.48
50 ml of 1N=150 ml of S(N), S= (50/150) (N)
99 (1/199)x 1 2.3
99.9 0.1/199.9 3.3
100 As in water 7
100.1 (0.1/200.1) 10.7
[OH-]= 0.1/200.1 p(OH)=3.3, pH=10.7
101 [OH-]= 1/201 p(OH) = 2.3
pH=11.7 Volume of alkali added (NaOH)
All the indicators, M.O. M.R. PhTh have indicator range pH lies in the reflexion region. Hence , all these can be used.
When 0.1 N HCl is titrated with 0.1 N NaOH, the inflexion range becomes narrower by two pH units(4.3-9.7)
With more dil strong acid and strong base the inflexion region becomes narrower. In this case the choice of indicator becomes narrower. M.Orange becomes unsuitable to detect the e.p. also, PhTh can’t be used.
BPB is suitable indicator for titration of very dilute strong acid. Methyl red is better than Methyl orange because of its higher indicator pH range for titration of strong dilute acid.
Presence of CO2 dissolved in water interferes with the indicator of
high pH ranges like PhTh, but acidic indicators like M.Orange is however, remains unaffected by the presence of dissolved CO
2.
Distilled water having pH 7.0 shows a pH of 5.7 when it is in equilibrium with air containing 0.03% CO
2 by volume. When satd. With CO
2
distilled water shows pH of 3.7 at 25°C
Dependence of the magnitude of end –point break on concentration. Curve1: 100 ml of 0.1M HCl versus 0.1 M NaOH.Curve 2: 100 ml of 0.01M HCl versus 0.01 M NaOH Curve 3: 100 ml of 0.001M HCl versus 0.001 M NaOH
2. Weak acid - strong base titrationCH3COOH (HAc) - NaOH0.1 N, 100 ml 0.1N
ml of alkaliadded
[H+] g-ion/L pH
0 √(1.75 x10-5 )x0.1 2.9
50 pH=4.8+log50/50 4.8(pKa)
99 pH=4.8 +log 99/1 6.8
99.9 0.1/199.9 7.8
100 pH=7+2.4+½ log(0.01) 8.9
100.1 pH due to 0.1 ml NaOH in 200.1ml soln
10.7
[OH-]= 0.1/200.1 p(OH)=3.3, pH=10.7
101 [OH-]= 1/201 p(OH) = 2.3
pH=11.7
HAc ⇋ H+ + Ac-
HAca
K
AcH
HAc
2
H
[H+] = √(Ka . c)
Since [H+]= [Ac-] only for pure HAcand [HAc] = c
(i) pH=½ pKa - ½log c
=½x4.8 -½log(0.1)=2.9
HAca
K
AcH
-AcH
HAcKa
HAc
Aclog
apKpH
This form of ionisation constant equation is called the Henderson- Hasselbalch equation. It is useful for calculating the pH of a weak acid soln containing its salt. Salt of weak acid and strong base HAc + OH- = Ac- + H2O
At equi.p. Ac- undergoes hydrolysis
Ac- + H2O ⇋HAc + OH-
Ac
OHHAc
hK
H
Hx
aKwK
Ac
OHHAch
Kc
2OH
[HAc] = [ OH-]
cKKOH aw ./2
KaCKwOH /.
cpKpKpOH aw log2
1
2
121
cpKpKpKwpH aw log
2
1
2
121
CpKpKpH aw log2
1
2
1
2
1
2.
3.
3. General eqn for calculating e.p. When an weak acid is titrated with a strong base and also when any salt of weak acid and strong base is dissolved in water
Inflection region narrower and on the alkaline pH side
As the titration curve indicates, methyl orange and methyl red can’t be used to detect the E.P but alkaline range indicator like PhTh, ThTh, Thymol blue can be used as indicator. For the acids with Ka. As low as 10-7, the e.p. Is at pH=10. i.e., at a still higher pH, but the rate of change in pH in the neighbourhood of the theoretical or stoichiometric e.p. is very little pronounced due to considerable hydrolysis.
Dependence of the titration curve of weak acid on concentration. Curve1: 100 ml of 0.1M HOAc versus 0.1 M NaOH. Curve 2: 100 ml of 0.01M HOAc l versus 0.01 M NaOH, Curve 3: 100 ml of 0.001M HOAc versus 0.001 M NaOH
Salt of weak acid, strong electrolyte Bronsted Base
Sodium acetate is a weak base(conjugate base of weak acid).The weaker the conjugate acid , the
stronger the conjugate base,i.e., the more strongly the salt will combine with a proton as from the water
What is the pH when 25.00 mL of 0.20 M CH3COOH has been
titrated with 40.0 mL of 0.10 M NaOH? Solution:
1)Determine moles of acid and base before reaction:
CH3COOH: (0.20 mol/L) (0.02500 L) = 0.0050 mol
NaOH: (0.10 mol/L) (0.04000 L) = 0.0040 mol
2) Determine moles of acid and salt after reaction:
CH3COOH: 0.0050 mol - 0.0040 mol = 0.0010 mol
CH3COONa: 0.0040 mol
3) Use Henderson-Hasselbalch Equation to determine pH:
pH = 4.572 + log (0.0040/0.0010) pH = 4.572 + 0.602 pH = 5.354
3. Titration of Weak base with Strong acid
ml of acidadded
[H+] g-ion/L pH
0 14-2.37-0.5=11.1 11.1
50 14 - 4.8 – 0 = 9.2 (pKa of conjugate acid of the weak base)
9.2
99 14-4.8-log(99/1) = 7.2 7.2
99.9 14-4.8- log(99.9/1) = 6.2 6.2
100 7- 2.4 - ½log(0.05) = 5.25 5.25
100.1 S= (0.01/200.1)=3.8 3.8
0.1 mlx0.1N= S x 200.1 , S= 0.01/200.1
100 ml 0.1 N NH4OH vs.HCl(0.1N)NH4OH ⇋ NH4
+ + OH-
OH4NH
2OH
Since [NH4+]= [OH-] only for free
base and [NH4OH] = c
pOH=½ pKb - ½log c
OH
4NH
OH4
NH
bK
OHNHbKOH 4
(i) pH=pKw -½ pKb + ½log c
4NH
OH4NH-OH
bK
OH
4NH
OH4
NH
bK
OH4NH4NH
logbpKpOH
OH4NH
4NHlogbpKwpKpH
pH + pOH = pKw
pOH = pkw-pH
NH4OH +HCl⇋ NH4Cl + H2O
At equivalent point only NH4Cl is present, but NH
4+ undergoes hydrolysis(h)
NH4+ + H2O ⇋NH4OH + H+
4
4
NH
HOHNH
hK
H
H
bKwK
X
bKwK
C
2
Hbw KCKH /.
CpKpKpH bw log2
1
2
1
2
1
It is clear from the titration curve neither PhPh nor ThPh i.e., the alkaline range indicator can be used to detect the e.p in the titration of 0.1N NH4OH agt a strong acid. Indicators with pH range on the slightly acidic side such as M.O, M.R or BCG etc can be used for the purpose. BCG is suitable for titration of all weak bases with Kb greater than10-6 .
NH4Cl : a weak Bronsted acid will
follow hydrolysis
4. Titration of weak acid - weak base100 ml 0.1N CH3COOH VS. NH4OH (0.1N) aq NH3
At e.p. The pH will depend upon the relative strength of acid and base. In this case both the weak acid anion and the weak base cation undergo hydrolysis.
Ac- + H2O ⇋ HAc + OH-
NH4+ + H2O ⇋ NH4OH + H+
The hydrolytic equilibrium of a salt of weak acid and weak base is expressed by the eq.
ΑΜ
ΗΑΜΟΗh
Κ
OH
OHx
H
Hx
ΑΜ
ΗΑΜΟΗh
Κ
A
OHx
H
Hx
OΜ
ΗΑΜΟΗhΚ
H
bKaKwKKh
If x is the hydrolysis of 1 mol of the salt dissolved in V L of solution then the individual concns are:[MOH]= [HA]=x/V; [M+]= [A-] = (1-x)/V from eqn 1,
....eqn 1
2)(
2
V
x-1
V
x-1
V
x
V
x
hΚx-1
x
)(
hKx-1
x
....eqn 2
....eqn 3
M+ + A- +H2O MOH +HA⇋
HA ⇋ H+ + A-
HA
AHaK
-A
HAaKH hKKa
x
xaK .1
bKwKaK
bKaKwK
aKH.
.
bpK2
1apK
2
1wpK
2
1pH
If the ionisation constant of the acid and the base are equal, that is Ka=Kb, pH= ½pKw =7.0, pH of Ammonium acetate is 7.0+2.7 - 2.7 = 7.0
No conc. term for the salt produced appears
Hence, during titration of weak acid agt a weak base pH at e.p. is independent of the concn. of acid and base and depends on only the relative strength of acid and base.
Accordingly, no sharp colour change obtd. at e.p with any simple pH indicator. However, a mixed indicator of suitable composition which exhibits a sharp colour change over a very limited pH range may sometimes be used for the detection of e.p.Thus, HAc-NH4OH titration, neutral red + methylene blue has been used with some success. On the whole it is better to avoid such titrations by indicator method. Usually potentiometric and conductometric titrations are preferable in such cases.
There is no sharp change in the pH during the titration. Hence, no sharp equivalence point can be obtained with common indicators. However, a mixed indicator, which shows a sharp colour change over limited pH range may be used.
Titration of Poly basic acidsFor a dibasic acid if the diff.between primary and secondary dissociation constant is very large, K1/K2 ≥104, the solution of acid behaves like a mixture of two mono-basic acids having independent dissociation constant and during titration of these acids agt. a strong base, we can have two seperate e.p. Thus for H2SO3(K1= 1.7x 10-2 , K2=1x 10-7) there will be a sharp change of pH at the first e.p. But the 2nd e.p satge is less pronounced because K2 is very low. However, ThPh indicator the 2nd e.p. Can be well detected.
H2CO3 (K1= 4.3x 10-7 , K2=5.6x 10-11) it can be seen from K1 and K2 value that 2nd dissociation stage is extremely weak and no suitable indicator is available for direct titration of H2CO3 as a dibasic acid.Provided the 1st dissociation stages of the acid is weak and K1 can be neglected in comparison with concn C we can have
21KKH
pH=½pK1 +½pK2 CK
CKKH
1
21 Usual expression
For H2CO3 , pH (e.p.)= 8.2 With a knowledge of the pH at the stoichiometric e.p and also by knowing the course of neutralisation curve we select an appropriate indicator for the titration of any dibasic acid for which K1/K2 is at least 104.
H3PO4 (K1= 7.5x10-3, K2=6.2 x10-8, K3=5x10-13
H3PO4 in soln will behave as the mixture of 3 monobasic acids because K1/K2 and K2/K3 ratios are greater than 104.Neutralisation with a strong base can proceed almost completely to the end of the 1st stage before the 2nd dissociation stage is affected and the 2nd stage can be neutralised completely before the tertiary stage is apparent. The pH–change during titration of H3PO4 agt.caustic soda soln( NaOH) can be shown as ;
H3PO4 is a good example of a titration where the first two equivalence points, corresponding to base reaction with the first and second protons, respectively, are clearly visible.(sharp change in pH at the equivalence point)
The acid dissociation constants for H3PO4 are quite different from each other with pKa's of 2.15, 7.2, and 12.15 Because the pKa are so different, the protons are reacted at different pH's. This is illustrated in the plot of the relative fraction as a fn of pH
pH = pK1 +log10 = pK1 = 2.1 43
42
POH
POH
(i)With 50% of 1st acidity (1st replaceable H+ half neutralised)
(ii) At 1st e.p. pH = ½pK1 + ½pK2 = ½(2.1+7.2)= 4.65
(iii) With 1.5 equivalence of alkali added,
pH = pK2 +log10 = pK2 = 7.2
42
24
POH
HPO
(iv) With 2nd equivalence point,
pH = ½pK2 + ½pK3 = ½(7.2+12.3)= 9.75
(v) With 2.5 equivalence of alkali added,
24
HPO
34
PO
pH = pK3 +log10 = pK1 = 2.1(vi) With 3rd equivalence point,
pH = ½pKw + ½pK3 +½log C = ½(7+6.5-0.5)= 12.65
The pH at points where the relative fraction of two species are equal, e.g., where two relative concentration lines cross, have a simple relationship to the acid equilibration constants. For example, the first crossing occurs for [H3PO4] = [ H2PO4
-]. The relationship to pH is most easily found by recognizing that all principle species are given in the first proton ionization equation
Figure 1. Titration curve for titration of phosphoric acid with sodium hydroxide. The point marked "a" is the initial point. The pH of the solution equals pKa1, pKa2, and pKa3 at points b, d, and f, respectively. Points c, e, and g are the first, second, and third equivalence points, respectively. The points between a and c, between c and e, and between e and g are the first, second, and third buffer zones, respectively.