Strong acid and bases - Weak acid and bases - Dissociation constants and pK's
Acids are divided into two categories based
on the ease with which
they can donate protons to the solvent: i) strong acids and
ii) weak acids
Strong acids are acids that completely
dissociate in water. The reaction of an acid with its solvent
(typically H2O) is called an acid dissociation reaction.
Strong acids, such as HNO3, almost completely transfer their protons to the
solvent molecules:
HNO3(aq)
+ H2O(l) → H3O+(aq) + NO3–(aq)
In this reaction H2O serves as
the base. The hydronium ion, H3O+, is the conjugate acid
of H2O, and the nitrate ion is the conjugate base of HNO3.
It is the hydronium ion H3O+ that is the acidic species
in solution, and its concentration determines the acidity of the resulting
solution - pH of a strong acid.
The
common strong acids in aqueous solutions are given in Table I.1:
 |
|
Table I.1: Strong acids in aqueous
solutions
|
When a solution of 0,1 M HNO3
dissolves in water dissociates completely to 0,1 M H+ and 0,1 M NO3–.
Weak
acids, for example acetic acid, cannot completely donate their acidic protons
to the solvent. Instead, most of the acid remains undissociated, with only a
small fraction present as the conjugate
base (CH3COO–).
Weak
acids are acids that dissociate partially in water. The extent of dissociation
is given by the equilibrium constant.
Note:
A measure
of the relative strength of an acid is: i) the
equilibrium constant ka of the dissociation reaction of the acid
in water (depends on temperature) ii) the degree of dissociation α of the acid
in water (depends on the concentration of the acid an on temperature).
The
equilibrium constant for this reaction is called an acid
dissociation constant, ka, and is written as:
ka = [H3O+]
* [CH3COO–] / [CH3COOH] = 1.76 * 10-5
The magnitude of ka provides
information about the relative strength of a weak acid, with a smaller ka
corresponding to a weaker acid. The opposite, small pka values
characterize stronger acids.
Table
I.2 below gives the ka and pka values for a number of
commonly-encountered weak acids (25 ∘C).
Compound
|
ka
|
pka
|
Acetic
acid (CH3COOH)
|
1.76
x 10-5
|
4.75
|
Adipic
acid (CH2)4(COOH)2
|
3.71
x 10-5 Step 1
3.87
x 10-5 Step 2
|
4.43
4.41
|
Benzoic
acid (C6H5COOH)
|
6.46
x 10-5
|
4.19
|
Carbonic
acid (H2CO3)
|
4.3
x 10-7
5.61
x 10-11
|
6.37
10.25
|
Chloroacetic
acid (ClCH2CO2H)
|
1.4
x 10-3
|
2.85
|
Chromic
acid (H2CrO4)
|
1.8
x 10-1
3.2
x 10-7
|
0.74
6.49
|
Formic
acid (HCOOH)
|
1.77
x 10-4 (20 ○C)
|
3.75
|
Hydrocyanic
acid (HCN)
|
4.93
x 10-10
|
9.31
|
Hydrofluoric
acid (HF)
|
3.53
x 10-4
|
3.45
|
Hypobromous
acid (HBrO)
|
2.06
x 10-9
|
8.69
|
Hypochlorous
acid (HClO)
|
2.95
x 10-8
|
7.53
|
Hypoiodous
acid (HIO)
|
2.3
x 10-11
|
10.64
|
Iodic
acid (HIO3)
|
1.69
x 10-1
|
0.77
|
Maleic
acid
|
1.42
x 10-2
8.57
x 10-7
|
1.83
6.07
|
Nitrous
acid (HNO2)
|
4.6
x 10-4 (12,5 ○C)
|
3.37
|
Oxalic
acid (H2C2O4)
|
5.90
x 10-2
6.40
x 10-5
|
1.23
4.19
|
Periodic
acid
|
2.3
x 10-2
|
1.64
|
Phenol
(C6H5OH)
|
1.28
x 10-10
|
9.89
|
o-Phosphoric
acid (H3PO4)
|
7.52
x 10-3
6.23
x 10-8
|
2.12
7.21
|
Table I.2: The ka and pka values
for a number of commonly-encountered weak acids
Simirarly,
strong bases, such as NaOH, are bases that completely dissociate in water to
produce hydroxyl ion OH-:
NaOH
→ Na+ + OH-
When
0.1M NaOH dissolves in H2O dissociates to 0.1M Na+ and 0.1M OH-.
The
common strong bases in aqueous solutions are given in Table I.3:
Strong
bases in aqueous solutions
|
|
Group
1A metal hydroxides
|
LiOH,
NaOH, KOH, RbOH, CsOH
|
Group 2A metal hydroxides
|
Ca(OH)2,
Sr(OH)2, Ba(OH)2
|
Table I.3: Strong
bases in water
Weak bases
are bases that partially dissociate in water – only partially accept protons
from the solvent – and are characterized by base dissociation constant kb.
For example the base dissociation constant kb for the weak base
acetate ion is given by:
CH3COO- + H2O = OH- +
CH3COOH
kb = [OH-][CH3COOH] / [CH3COO–] = 5.71 * 10-10
The magnitude of kb provides
information about the relative strength of a weak base, with a smaller kb
corresponding to a weaker base.
Table
I.4 below gives the k and pkb values for a number of
commonly-encountered weak bases.
Compound
|
kb
|
pkb
|
Acetamide
(CH3CONH2)
|
2.5
x 10-13
|
12.60
|
Acetanilide
(CH3CONHPh)
|
4.1
x 10-14
|
13.39
|
Ammonium
hydroxide (NH4OH)
|
1.79
x 10-5
|
4.75
|
Diethylamine
(C2H5NHC2H5)
|
9.6
x 10-4
|
3.02
|
n-Diethylamine
|
3.65
x 10-8
|
7.44
|
Glycine
|
2.26
x 10-12
|
11.65
|
Methylamine
|
4.38
x 10-4
|
3.36
|
Table I.4: The kb
and pkb values for a number of commonly-encountered weak bases
What ranges of ka values characterize strong and weak acids? What are the corresponding degree of dissociation α values?
Type
of acid
|
ka
|
pka
|
Degree of dissociation (α) of acid (%)
|
Very
strong acid
|
> 0.1
|
< 1
|
90-100%
|
Moderately
strong acid
|
10-3 – 0.1
|
1-3
|
30-90%
|
Weak
acid
|
10-5 – 10-3
|
3-5
|
30-5%
|
Very
weak acid
|
10-15 – 10-5
|
5-15
|
5-1%
|
Extremely
weak acid
|
< 10-15
|
> 15
|
< 1%
|
Why proton transfers occur in acid-base reactions?
Acids are proton (H3O+) donors
while bases are proton acceptors. An acid, such as
HCl, donates a proton to a suitable base like H2O because the
products formed (H3O+ and Cl-) are of lower
free energy (ΔG)
than the reactants and this means energetically more favorable.
HCl(aq)
+ H2O(l) → H3O+(aq) + Cl–(aq)
The free energy (ΔG) for the ionization
reaction of HCl in Η2Ο is -40 kJ/mol. Such a
large negative ΔG
shows that the reaction lies well over to the right – formation of products is
highly favorable due to the lower free energy level (Fig. I.1). Therefore, proton transfers occur in acid-base reactions in solution
because are energetically favorable since the products are of lower energy than
the reactants.
 |
|
Fig. I.1: Formation
of products - H3O+
transfer – is highly favored in the ionization of HCl in water due to the lower
energy attained. The ΔG
for the reaction is -40 kJ/mol.
|
In the gas phase, however, ionization of HCl(g) happens with much difficulty and ΔG
= +1347 kJ/mol. This means that HCl(g)
does not spontaneously ionize in the gas phase—it does not lose protons at all.
Why then is HCl such a strong acid in water? The key to this problem is, of
course, the water. In the gas phase we would have to form an isolated proton (H3O+)
and chloride ion and this is energetically very unfavourable. In contrast, in
aqueous solution the proton is strongly attached to a water molecule to give
the very stable hydronium ion, H3O+, and the ions are no
longer isolated but solvated (Fig. I.2).
 |
|
Fig. I.2: Proton solvated – attached to water
molecules
|
Relevant Posts - Relevant Videos
Ionic equilibrium - A general expression of the pH of a strong acid
Chemical Equilibrium Calculations in Analytical Chemistry
pH of a strong acid – Examples
Strong Acids & Bases: pH Calculations involving mixtures of strong acids and bases
References
- J-L. Burgot “Ionic Equilibria in Analytical Chemistry”,Springer Science & Business Media, 2012
- J.N. Butler “Ionic Equilibrium – Solubility and pH calculations”, Wiley – Interscience, 1998
- Clayden,Greeves, Waren and Wothers “Organic Chemistry”, Oxford, 2012
- D. Harvey,“Modern Analytical Chemistry”, McGraw-Hill Companies Inc., 2000
- Toratane Munegumi, World J. of Chem. Education, 1.1, 12 (2013)
Key Terms
strong acid, strong base, pH calculation, [H+] concentration, pH, Kw, calculate the pH of a strong acid, calculate the pH of a strong base, strong acids and bases,pH of a strong acid, pH of a strong base,pH of a weak acid, pH of a weak base, ionic equilibrium, conjugate base, conjugate acid, dissociation constant, degree of dissociation,hydroxyl ion, hydronium ion
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