Chapter 4: Acids and Bases | Inorganic Chemistry

Introduction Overview

This chapter focuses on the wide variety of species classified as acids and bases. The first part describes the Brønsted definition, in which an acid is a proton donor and a base is a proton acceptor. Proton transfer equilibria can be discussed quantitatively in terms of acidity constants, which measure the tendency for species to donate protons.

In the second part, we introduce the Lewis definition of acids and bases, which deals with reactions involving electron-pair sharing between a donor (the base) and an acceptor (the acid). This broadening enables us to extend our discussion to include species that do not contain protons and to reactions in nonprotic media.

The original distinction between acids and bases was based, hazardously, on criteria of taste and feel: acids were sour and bases felt soapy. A deeper chemical understanding emerged from Arrhenius's (1884) conception of an acid as a compound that produced hydrogen ions in water.

SO₂(g)

+

H₂O(l)

→

HOSO₂⁻(aq)

+

H⁺(aq)

Formation of acid rain - a classic acid-base reaction

4.1 Brønsted Acidity

A Brønsted acid is a proton donor and a Brønsted base is a proton acceptor. A proton has no separate existence in chemistry and is always associated with other species. A simple representation of a hydrogen ion in water is as the hydronium ion, H₃O⁺.

Johannes Brønsted in Denmark and Thomas Lowry in England proposed (in 1923) that the essential feature of an acid-base reaction is the transfer of a hydrogen ion, H⁺, from one species to another. In this context, a hydrogen ion is often referred to as a proton.

Brønsted Acid:

A proton donor

Brønsted Base:

A proton acceptor

An example of a Brønsted acid is hydrogen fluoride, HF, which can donate a proton to another molecule, such as H₂O, when it dissolves in water:

HF(g) + H₂O(l) → H₃O⁺(aq) + F⁻(aq)

An example of a Brønsted base is ammonia, NH₃, which can accept a proton from a proton donor:

H₂O(l) + NH₃(aq) → NH₄⁺(aq) + OH⁻(aq)

Water is an example of an amphiprotic substance - a substance that can act as both a Brønsted acid and a Brønsted base.

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Hydronium Ion

H₃O⁺

O-H bond: 101 pm
H-O-H angle: 100-120°

🔵💧💧💧

Hydrated Hydronium

H₉O₄⁺

Better representation of proton in water

(a) Conjugate Acids and Bases

When a species donates a proton, it becomes the conjugate base; when a species gains a proton, it becomes the conjugate acid. Conjugate acids and bases are in equilibrium in solution.

The general Brønsted equilibrium can be written as:

Acid₁ + Base₂ ⇌ Acid₂ + Base₁

The species Base₁ is called the conjugate base of Acid₁, and Acid₂ is the conjugate acid of Base₂. Thus, F⁻ is the conjugate base of HF and H₃O⁺ is the conjugate acid of H₂O.

EXAMPLE 4.1 Identifying acids and bases

Identify the Brønsted acid and its conjugate base in the following reactions:

(a) HSO₄⁻(aq) + OH⁻(aq) → H₂O(l) + SO₄²⁻(aq)

(b) PO₄³⁻(aq) + H₂O(l) → HPO₄²⁻(aq) + OH⁻

Answer: (a) The hydrogensulfate ion, HSO₄⁻, transfers a proton to hydroxide; it is therefore the acid and the SO₄²⁻ ion produced is its conjugate base. (b) The H₂O molecule transfers a proton to the phosphate ion acting as a base; thus H₂O is the acid and the OH⁻ ion is its conjugate base.

Identify the acid, base, conjugate acid, and conjugate base in: NH₃(aq) + H₂S(aq) → NH₄⁺(aq) + HS⁻(aq)

(b) The Strengths of Brønsted Acids

The strength of a Brønsted acid is measured by its acidity constant, and the strength of a Brønsted base is measured by its basicity constant; the stronger the base, the weaker is its conjugate acid.

The concept of pH is fundamental:

pH = −log[H₃O⁺], and hence [H₃O⁺] = 10⁻ᵖᴴ (4.1)

The strength of a Brønsted acid in aqueous solution is expressed by its acidity constant (or 'acid ionization constant'), Kₐ:

HX(aq) + H₂O(l) ⇌ H₃O⁺(aq) + X⁻(aq) Kₐ = [H₃O⁺][X⁻]/[HX] (4.2)

A value Kₐ ≪ 1 implies that [HX] is large with respect to [X⁻], and so proton retention by the acid is favoured. The experimental value of Kₐ for hydrogen fluoride in water is 3.5 × 10⁻⁴, indicating that under normal conditions only a very small fraction of HF molecules are deprotonated.

EXAMPLE 4.2 Calculating acidity constants

The pH of 0.145 M CH₃COOH(aq) is 2.80. Calculate Kₐ for ethanoic acid.

Answer: The concentration of H₃O⁺ is obtained from the pH: [H₃O⁺] = 10⁻²·⁸⁰ = 1.6 × 10⁻³ mol dm⁻³. Each deprotonation event produces one H₃O⁺ ion and one CH₃CO₂⁻ ion, so [CH₃CO₂⁻] = [H₃O⁺]. The molar concentration of the remaining acid is (0.145 − 0.0016) = 0.143 mol dm⁻³.

Kₐ = (1.6 × 10⁻³)² / 0.143 = 1.7 × 10⁻⁵

This value corresponds to pKₐ = 4.77.

For hydrofluoric acid, Kₐ = 3.5 × 10⁻⁴. Calculate the pH of 0.10 M HF(aq).

The basicity constant, Kb, is similarly defined:

B(aq) + H₂O(l) ⇌ HB⁺(aq) + OH⁻(aq) Kb = [HB⁺][OH⁻]/[B] (4.3)

The autoprotolysis constant of water is:

2 H₂O(l) ⇌ H₃O⁺(aq) + OH⁻(aq) Kw = [H₃O⁺][OH⁻] = 1.00 × 10⁻¹⁴ at 25°C

An important relationship links the strength of a base to its conjugate acid:

KₐKb = Kw and pKₐ + pKb = pKw = 14 (4.4, 4.6)

The Kb of ammonia in water is 1.8 × 10⁻⁵. It follows that Kₐ of the conjugate acid NH₄⁺ is:

Kₐ = Kw/Kb = (1 × 10⁻¹⁴)/(1.8 × 10⁻⁵) = 5.6 × 10⁻¹⁰

(c) Strong and Weak Acids and Bases

An acid or base is classified as either weak or strong depending on the size of its acidity constant.

Strong acid: pKₐ < 0 (Kₐ > 1, usually Kₐ ≫ 1) - almost fully deprotonated in solution
Weak acid: pKₐ > 0 (Kₐ < 1) - equilibrium favours nonionized acid
Strong base: Almost fully protonated in water (e.g., O²⁻ → OH⁻)
Weak base: Only partially protonated (e.g., NH₃)

The conjugate base of any strong acid is a weak base, because it is thermodynamically unfavourable for such a base to accept a proton.

(d) Polyprotic Acids

A polyprotic acid loses protons in succession, and successive deprotonations are progressively less favourable; a distribution diagram summarizes how the fraction of each species present depends on the pH of the solution.

For a diprotic acid like H₂S, there are two successive proton donations:

H₂S(aq) + H₂O(l) ⇌ HS⁻(aq) + H₃O⁺(aq) Kₐ₁ = 9.1 × 10⁻⁸ (pKₐ₁ = 7.04)

HS⁻(aq) + H₂O(l) ⇌ S²⁻(aq) + H₃O⁺(aq) Kₐ₂ ≈ 1.1 × 10⁻¹⁹ (pKₐ₂ = 19)

The decrease in Kₐ is consistent with an electrostatic model: in the second deprotonation, a proton must separate from a centre with one more negative charge than in the first deprotonation.

Distribution Diagram for Phosphoric Acid (H₃PO₄)

H₃PO₄

H₂PO₄⁻

HPO₄²⁻

PO₄³⁻

pKₐ₁ = 2.12, pKₐ₂ = 7.21, pKₐ₃ = 12.68

(e) Factors Governing Strengths of Brønsted Acids and Bases

Proton affinity is the negative of the gas-phase proton-gain enthalpy. The proton affinities of p-block conjugate bases decrease to the right along a period and down a group. Proton affinities are influenced by solvation, which stabilizes species carrying a charge.

The proton affinity, Aₚ, of A⁻ is given by:

Aₚ(A⁻) = B(H−A) + I(H) − Aₑ(A) (4.8)

Where:

B(H−A) is the H−A bond dissociation enthalpy
I(H) is the ionization energy of hydrogen
Aₑ(A) is the electron affinity of A

The Born equation describes the Gibbs energy of solvation:

ΔsolvG° = −(NAz²e²)/(8πε₀r) × (1 − 1/εr) (4.9)

The effective proton affinity of I⁻ in water is 1068 kJ mol⁻¹ compared to 1314 kJ mol⁻¹ in the gas phase, showing that the I⁻ ion is stabilized by hydration. The effective proton affinity is also smaller than that of water (1130 kJ mol⁻¹), which is consistent with HI being a strong acid in water.

Table 4.1 Acidity Constants at 25°C

Acid	HA	A⁻	Kₐ	pKₐ
Hydriodic	HI	I⁻	10¹¹	−11
Perchloric	HClO₄	ClO₄⁻	10¹⁰	−10
Hydrobromic	HBr	Br⁻	10⁹	−9
Hydrochloric	HCl	Cl⁻	10⁷	−7
Sulfuric	H₂SO₄	HSO₄⁻	10²	−2
Nitric	HNO₃	NO₃⁻	10²	−2
Hydronium ion	H₃O⁺	H₂O	1	0.0
Phosphoric	H₃PO₄	H₂PO₄⁻	7.5 × 10⁻³	2.12
Hydrofluoric	HF	F⁻	3.5 × 10⁻⁴	3.45
Ethanoic	CH₃COOH	CH₃CO₂⁻	1.74 × 10⁻⁵	4.76
Carbonic	H₂CO₃	HCO₃⁻	4.3 × 10⁻⁷	6.37
Hydrogen sulfide	H₂S	HS⁻	9.1 × 10⁻⁸	7.04
Ammonium ion	NH₄⁺	NH₃	5.6 × 10⁻¹⁰	9.25
Hydrocyanic	HCN	CN⁻	4.9 × 10⁻¹⁰	9.31
Hydrogensulfide ion	HS⁻	S²⁻	1.1 × 10⁻¹⁹	19

4.2-4.5 Characteristics of Brønsted Acids

Aqua acids, hydroxoacids, and oxoacids are typical of specific regions of the periodic table.

There are three classes of acids to consider:

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Aqua Acid

[Fe(OH₂)₆]³⁺

Acidic proton on coordinated water molecule

🔴⚪⚪⚪⚪⚪

Hydroxoacid

Te(OH)₆

Acidic proton on hydroxyl group without neighboring oxo group

🟡🔴🔴

Oxoacid

H₂SO₄

Acidic proton on hydroxyl group with oxo group attached

4.2 Periodic Trends in Aqua Acid Strength ▼

The strengths of aqua acids typically increase with increasing positive charge of the central metal ion and with decreasing ionic radius; exceptions are commonly due to the effects of covalent bonding.

The acidity should increase with increasing z (charge) and with decreasing r₊ (radius). Small, highly charged cations that are not easily polarized are hard and form complexes with small anions. Large cations are more polarizable and are soft.

EXAMPLE 4.4 Accounting for trends in aqua acid strength

Account for the trend in acidity: [Fe(OH₂)₆]²⁺ < [Fe(OH₂)₆]³⁺ < [Al(OH₂)₆]³⁺ ≈ [Hg(OH₂)]²⁺

Answer: The weakest acid is the Fe²⁺ complex on account of its relatively large ionic radius and low charge. The increase of charge to +3 increases the acid strength. The greater acidity of Al³⁺ can be explained by its smaller radius. The anomalous Hg²⁺ complex reflects the failure of an ionic model—there is large transfer of positive charge to oxygen as a result of covalent bonding.

4.3 Simple Oxoacids & Pauling's Rules ▼

The strengths of a series of oxoacids containing a specific central atom with a variable number of oxo and hydroxyl groups are summarized by Pauling's rules.

The trends can be systematized using two empirical rules (p = number of oxo groups, q = number of hydroxyl groups):

Pauling's Rule 1:

For the oxoacid OₚE(OH)q, pKₐ ≈ 8 − 5p

Pauling's Rule 2:

The successive pKₐ values of polyprotic acids (q > 1) increase by 5 units for each successive proton transfer.

p value	Predicted pKₐ	Acid strength	Example
0	≈ 8	Very weak	HOCl (7.2)
1	≈ 3	Weak	H₂CO₃ (3.6)
2	≈ −2	Strong	H₂SO₄ (−1.9)
3	≈ −7	Very strong	HClO₄ (−10)

4.4 Anhydrous Oxides - Acidic, Basic, and Amphoteric ▼

Metallic elements typically form basic oxides; nonmetallic elements typically form acidic oxides. Amphoteric oxides react with both acids and bases.

Acidic Oxide:

An oxide that reacts with water to release protons or reacts with aqueous base

CO₂(g) + OH⁻(aq) → O₂C(OH)⁻(aq)

Basic Oxide:

An oxide to which a proton is transferred when it dissolves in water

BaO(s) + H₂O(l) → Ba²⁺(aq) + 2 OH⁻(aq)

Amphoteric Oxide:

An oxide that reacts with both acids and bases

Al₂O₃(s) + 6 H₃O⁺(aq) → 2 [Al(OH₂)₆]³⁺(aq)

Al₂O₃(s) + 2 OH⁻(aq) → 2 [Al(OH)₄]⁻(aq)

Amphoterism is observed for lighter elements of Groups 2 and 13 (BeO, Al₂O₃, Ga₂O₃), d-block elements in high oxidation states (MoO₃, V₂O₅), and heavier elements of Groups 14 and 15 (SnO₂, Sb₂O₅).

4.5 Polyoxo Compound Formation ▼

Acids containing the OH group condense to form polyoxoanions; polycation formation from simple aqua cations occurs with the loss of H₂O. Polyoxoanions account for most of the mass of oxygen in the Earth's crust.

An example is the formation of the diphosphate ion from orthophosphate:

2 PO₄³⁻ + 2 H₃O⁺ → P₂O₇⁴⁻ + 3 H₂O

The formation of polyoxoanions is important for early d-block ions in their highest oxidation states, particularly V(V), Mo(VI), W(VI), and Cr(VI), for which the term 'polyoxometallates' is used.

Polyphosphates are biologically important—the key to energy exchange in metabolism is the hydrolysis of ATP to ADP:

ATP⁴⁻ + 2 H₂O → ADP³⁻ + HPO₄²⁻ + H₃O⁺ ΔrG° = −41 kJ mol⁻¹ at pH 7.4

4.6-4.7 Lewis Acidity

A Lewis acid is an electron-pair acceptor. A Lewis base is an electron-pair donor.

The Brønsted–Lowry theory of acids and bases focuses on proton transfer. A more general theory was introduced by G.N. Lewis in 1923. The fundamental reaction is the formation of a complex (or adduct), A–B, in which A and :B bond together by sharing the electron pair supplied by the base.

The terms Lewis acid and base are used in discussions of equilibrium (thermodynamic) properties. In the context of reaction rates (kinetics), an electron-pair donor is called a nucleophile and an electron-pair acceptor is called an electrophile.

empty

Acid (A)

LUMO

+

↑↓

Base (:B)

HOMO

→

↑↓

Complex (A–B)

Bonding MO

The Lewis acid provides an empty orbital (usually the LUMO), and the Lewis base provides a full orbital (usually the HOMO). The newly formed bonding orbital is populated by the two electrons supplied by the base.

4.6 Examples of Lewis Acids and Bases

Possibilities for Lewis acid behavior include:

Incomplete octet: A molecule like B(CH₃)₃ can complete its octet by accepting an electron pair
Metal cation: Can accept electron pairs in coordination compounds (e.g., [Co(OH₂)₆]²⁺)
Rearranged valence electrons: CO₂ acts as Lewis acid when forming HCO₃⁻
Expanded valence shell: Formation of [SiF₆]²⁻ from SiF₄ and 2F⁻

EXAMPLE 4.7 Identifying Lewis acids and bases

Identify the Lewis acids and bases in: (a) BrF₃ + F⁻ → BrF₄⁻, (b) KH + H₂O → KOH + H₂

Answer: (a) The acid BrF₃ accepts a pair of electrons from the base F⁻. (b) The saline hydride KH provides H⁻ which is a Lewis base that reacts with H₂O to drive out OH⁻, another Lewis base.

4.7 Group Characteristics of Lewis Acids

Group 13 Lewis Acids (Boron & Aluminum) ▼

The ability of boron trihalides to act as Lewis acids generally increases in the order BF₃ < BCl₃ < BBr₃; aluminium halides are dimeric in the gas phase and are used as catalysts in solution.

This order is opposite to electronegativity expectations! The explanation is that halogen atoms in BX₃ form π bonds with the empty B2p orbital, and these must be disrupted for complex formation. Small F atoms form the strongest π bonds.

Aluminium chloride (Al₂Cl₆) is widely used as a Lewis acid catalyst for organic reactions like Friedel–Crafts alkylation:

RCl + AlCl₃ → R⁺ + [AlCl₄]⁻

Group 14-17 Lewis Acids ▼

Group 14: Silicon tetrahalides show acidity in order SiF₄ > SiCl₄ > SiBr₄ > SiI₄. Tin(II) chloride is both a Lewis acid and base!

Group 15: SbF₅ is one of the most widely studied Lewis acids and forms superacids with HF.

Group 16: SO₂ is both a Lewis acid and base. SO₃ is a strong Lewis acid (exothermic reaction with water → H₂SO₄).

Group 17: Br₂ and I₂ act as mild Lewis acids through their low-lying antibonding orbitals. The color change of iodine in different solvents demonstrates this—violet in nondonor solvents, brown in Lewis base solvents like acetone.

I₂(s) + I⁻(aq) → I₃⁻(aq) K = 725

4.8-4.10 Reactions and Properties of Lewis Acids and Bases

Reactions of Lewis acids and bases are widespread in chemistry, industry, and biology. Examples include:

Cement production (CaO + aluminosilicates)
CO₂ removal using amine scrubbers
Carbon monoxide toxicity (CO binding to Fe(II) in hemoglobin)
Friedel–Crafts reactions in organic synthesis

4.8 Fundamental Types of Reaction

Complex Formation

A

+

:B

→

A−B

Displacement Reaction

B−A

+

:B′

→

:B

+

A−B′

Metathesis (Double Displacement)

A−B

+

A′−B′

→

A−B′

+

A′−B

4.9 Hard and Soft Acids and Bases (HSAB)

Hard and soft acids and bases are identified empirically by the trends in stabilities of the complexes they form: hard acids tend to bind to hard bases and soft acids tend to bind to soft bases.

The two classes are identified by their opposite order of complex stabilities with halide ions:

Hard acids: I⁻ < Br⁻ < Cl⁻ < F⁻ (stability increases)
Soft acids: F⁻ < Cl⁻ < Br⁻ < I⁻ (stability increases)

HARD

Ionic bonding dominant

Acids:

H⁺, Li⁺, Na⁺, K⁺
Be²⁺, Mg²⁺, Ca²⁺
Cr³⁺, Al³⁺, Fe³⁺
BF₃, SO₃

Bases:

F⁻, OH⁻, H₂O
NH₃, CO₃²⁻
NO₃⁻, SO₄²⁻
PO₄³⁻, ClO₄⁻

BORDERLINE

Mixed character

Acids:

Fe²⁺, Co²⁺, Ni²⁺
Cu²⁺, Zn²⁺, Pb²⁺
SO₂, BBr₃

Bases:

NO₂⁻, SO₃²⁻
Br⁻, N₃⁻, N₂
C₆H₅N (pyridine)
SCN⁻ (N-bound)

SOFT

Covalent bonding dominant

Acids:

Cu⁺, Ag⁺, Au⁺
Hg²⁺, Pt²⁺, Pd²⁺
Cd²⁺, Tl⁺
BH₃

Bases:

H⁻, R⁻, CN⁻, CO
I⁻, SCN⁻ (S-bound)
R₃P, R₂S
C₆H₆ (benzene)

The bonding between hard acids and bases is predominantly ionic or dipole-dipole. Soft acids and bases are more polarizable, so the interaction has more covalent character.

The terrestrial distribution of elements reflects hard-soft principles: Hard cations like Li⁺, Mg²⁺, Ti³⁺ are found with hard base O²⁻. Soft cations like Cd²⁺, Pb²⁺, Sb²⁺ are found with soft anions S²⁻, Se²⁻, Te²⁻.

4.10 Thermodynamic Acidity Parameters (Drago-Wayland Equation)

The standard enthalpies of complex formation are reproduced by the E and C parameters of the Drago-Wayland equation that reflect the ionic and covalent contributions to the bond.

−ΔfH°(A−B)/kJ mol⁻¹ = E_AE_B + C_AC_B (4.10)

The parameters E and C represent 'electrostatic' and 'covalent' factors, respectively. This equation is useful for reactions in nonpolar solvents and gas phase, but is limited mainly to neutral molecules.

From Table 4.5: For BF₃, E = 21.2, C = 3.31; for NH₃, E = 2.78, C = 7.98.
Calculated: ΔfH° = −[(21.1 × 2.79) + (3.31 × 7.98)] = −85.28 kJ mol⁻¹
Experimental: −84.7 kJ mol⁻¹ ✓

4.11-4.13 Nonaqueous Solvents

Not all inorganic chemistry takes place in aqueous media. The properties of acids and bases are significantly altered by using nonaqueous solvents.

4.11 Solvent Levelling

A solvent with a large autoprotolysis constant can be used to discriminate between a wide range of acid and base strengths.

Any Brønsted acid stronger than H₃O⁺ in water donates a proton to H₂O and forms H₃O⁺. Consequently, no acid significantly stronger than H₃O⁺ can remain protonated in water. This is called the levelling effect.

Acids are levelled if pKₐ < 0 in the solvent
Bases are levelled if pKₐ > pKsol in the solvent
The discrimination window ranges from pKₐ = 0 to pKsol

Interactive pH Scale

0Strong Acid

7Neutral

14Strong Base

Hover over the pH scale to see examples

4.12 The Solvent-System Definition

The solvent-system definition extends the Brønsted-Lowry definition to include species that do not participate in proton transfer.

For an aprotic solvent like bromine trifluoride:

2 BrF₃(l) ⇌ BrF₂⁺(sol) + BrF₄⁻(sol)

Acid: Any solute that increases the concentration of the cation (BrF₂⁺)
Base: Any solute that increases the concentration of the anion (BrF₄⁻)

4.13 Solvents as Acids and Bases

Liquid Ammonia

NH₃

bp

−33.5°C

pKam

33

εr

24

Type

Basic

Dissolves alkali metals to give blue solutions with solvated electrons

Hydrogen Fluoride

HF

bp

19.5°C

εr

84

Type

Highly Acidic

Hazard

⚠️ Toxic

Conjugate base is HF₂⁻; only very strong acids function as acids in HF

Sulfuric Acid

H₂SO₄

mp

10.4°C

εr

100

Type

Acidic

Viscosity

High

Complex autoionization; generates NO₂⁺ for nitration reactions

DMSO

(CH₃)₂SO

bp

189°C

pKdmso

37

εr

46

Type

Basic

Wide discrimination window; hard (O) and soft (S) donor

Ionic Liquids

[R₄N⁺][AlCl₄⁻]

mp

< 100°C

Volatility

Very low

Type

Tunable

Use

Catalysis

Polar, nonvolatile; can provide very high concentrations of Lewis acids

Supercritical CO₂

scCO₂

Tc

31°C

Pc

73 atm

Type

Amphoteric

Green

✓

Low viscosity, nonflammable; used for decaffeination and green chemistry

4.14-4.15 Applications of Acid-Base Chemistry

4.14 Superacids and Superbases

Superacids are more efficient proton donors than anhydrous sulfuric acid. Superbases are more efficient proton acceptors than the hydroxide ion.

Superacids are formed when a powerful Lewis acid is dissolved in a powerful Brønsted acid. They can be up to 10¹⁸ times more acidic than H₂SO₄.

SbF₅(l) + 2 HSO₃F(l) → H₂SO₃F⁺(sol) + SbF₅SO₃F⁻(sol)

An equimolar mixture of SbF₅ and HSO₃F is known as "magic acid", named for its ability to dissolve candle wax. Superacids have been used to observe reactive cations such as S₈²⁺, H₃O₂⁺, Xe₂⁺, and HCO⁺.

Superbases are usually salts of Group 1 and 2 cations with small, highly charged anions:

Li₃N(s) + 3 H₂O(l) → 3 Li(OH)(aq) + NH₃(g)

CaH₂(s) + 2 H₂O(l) → Ca(OH)₂(s) + 2 H₂(g)

4.15 Heterogeneous Acid-Base Reactions

The surfaces of many catalytic materials and minerals have Brønsted and Lewis acid sites.

Surface acids (solids with high surface area and Lewis acid sites) are used as catalysts in the petrochemical industry. The most well-known class is zeolites, which are widely used as environmentally benign heterogeneous catalysts.

Silica surfaces: Moderate Brønsted acidity (similar to acetic acid)
Aluminosilicates: Strong Brønsted and Lewis acid sites
Solid acids: Used in green chemistry to replace hazardous liquid acids

Surface modification reactions use Brønsted acid sites:

Si−OH + HOSiR₃ → Si−O−SiR₃ + H₂O

This procedure expands the range of stationary phases for chromatography and can be used to treat glassware for proton-sensitive compounds.

Summary Key Concepts

Brønsted Theory

✓ Acids donate protons
✓ Bases accept protons
✓ Kₐ and pKₐ measure acid strength
✓ KₐKb = Kw for conjugate pairs

Lewis Theory

✓ Acids accept electron pairs
✓ Bases donate electron pairs
✓ Forms complexes/adducts
✓ Applies to aprotic systems

HSAB Principle

✓ Hard acids prefer hard bases
✓ Soft acids prefer soft bases
✓ Hard = ionic bonding
✓ Soft = covalent bonding

Solvent Effects

✓ Levelling limits acid/base range
✓ Discrimination window = 0 to pKsol
✓ Superacids > H₂SO₄
✓ Superbases > OH⁻