2024 Chemical Energetics Lecture Notes (Teacher) PDF

Summary

This document is a lecture summary on Chemical Energetics for Semester 1 of 2024. It covers topics like standard conditions, enthalpy change of reactions, calorimetry, bond energy, Hess's Law, entropy, and Gibbs free energy for H2 Chemistry students.

Full Transcript

Chemical Energetics 2024 Semester 1

CATHOLIC JUNIOR COLLEGE
H2 CHEMISTRY (Syllabus 9729)

CHEMICAL ENERGETICS

Learning Outcomes
Students should be able to:
(a) explain that most chemical reactions are accompanied by energy changes, principally in the form
of heat, usually associated with the breaking and forming of chemical bonds; the reaction can be
exothermic. (H negative) or endothermic (H positive)
(b) construct and interpret an energy profile diagram, in terms of the enthalpy change of the reaction
and of the activation energy (See also Section 8)
(c) explain and use the terms:
(i) enthalpy change of reaction and standard conditions, with particular reference to: formation;
combustion; hydration; solution; neutralisation; atomization
(ii) bond energy (H positive, i.e. bond breaking) (see also Section 2)
(iii) lattice energy (H negative, i.e. gaseous ions to solid lattice)
(d) calculate enthalpy changes from appropriate experimental results, including the use of the
relationship: heat change = mcT
(e) explain, in qualitative terms, the effect of ionic charge and of ionic radius on the numerical
magnitude of a lattice energy
(f) apply Hess’ Law to construct simple energy cycles, e.g. Born–Haber cycle, and carry out
calculations involving such cycles and relevant energy terms (including ionisation energy and
electron affinity), with particular reference to:
(i) determining enthalpy changes that cannot be found by direct experiment, e.g. an
enthalpy change of formation from enthalpy changes of combustion
(ii) the formation of a simple ionic solid and of its aqueous solution
(iii) average bond energies
(g) explain and use the term entropy
(h) discuss the effects on the entropy of a chemical system by the following:
change in temperature
(i)
(ii)
change in phase
(iii)
change in the number of particles (especially for gaseous systems)
(iv)
mixing of particles
[quantitative treatment is not required]
(i) predict whether the entropy change for a given process or reaction is positive or negative
(j) state and use the equation involving standard Gibbs free energy change of reaction, ΔG o : ΔG o
= ΔH o – TΔS o
[The calculation of standard entropy change, ΔS o , for a reaction using standard entropies, S o, is
not required]
(k) state whether a reaction or process will be spontaneous by using the sign of ΔG o
(l) understand the limitations in the use of ΔG o to predict the spontaneity of a reaction
(m) predict the effect of temperature change on the spontaneity of a reaction, given standard
enthalpy and entropy changes

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Contents
1. INTRODUCTION................................................................................................. 3
1.1 Enthalpy and Enthalpy Change..................................................................... 3
1.1 Standard Conditions...................................................................................... 4
2. ENTHALPY CHANGE OF REACTION, H.......................................................... 5
2.1 Exothermic and Endothermic Reactions........................................................ 5
2.2 Thermochemical Equations........................................................................... 6
3. CALCULATION OF ENTHALPY CHANGES, H.............................................. 8
3.1 Calorimetry (Experimental Determination of Enthalpy Changes using the
Calorimeter)............................................................................................................ 8
(A) Standard Enthalpy Change of Combustion, ΔHco........................................... 12
(B) Standard Enthalpy Change of Neutralisation, Hno........................................ 15
3.2 Bond Energy (only for covalent bonds)........................................................ 19
3.3 Use of Hess’ Law......................................................................................... 21
(C) Standard Enthalpy Change of Formation, Hfo.............................................. 21
3.3.1 Hess’ Law............................................................................................. 22
3.3.2 Other Energy Changes......................................................................... 27
(D) Standard Enthalpy Change of Hydration, Hhydo............................................ 27
(E) Standard Enthalpy Change of Solution, Hsolo................................................ 29
(F) Lattice Energy (Revision: Chemical Bonding)................................................. 32
(G) Standard Enthalpy Change of Atomisation Hato........................................... 34
(H) Ionisation Energy (Revision: Atomic Structure).............................................. 35
(I) Electron Affinity................................................................................................ 35
3.3.3 Born–Haber Cycle................................................................................ 36
3.3.4 Energy Level Diagram.......................................................................... 38
Summary of methods to find enthalpy change......................................................... 41
4. Idea of Spontaneous Processes....................................................................... 42
4.1 Entropy........................................................................................................ 42
4.2 Gibbs Free Energy...................................................................................... 48
Answers to Thinking Questions............................................................................ 54
Chemical Energetics summary:............................................................................ 55

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Chemical Energetics 2024 Semester 1

1. INTRODUCTION
Learning Outcome:
a) explain that most chemical reactions are accompanied by energy changes, principally in the form of
heat

Processed food that is sold in supermarkets normally carries a
nutrition label that lists the energy value of the food in kilojoules (kJ)
or calories. What does this “energy value” refer to? This is the
chemical energy made available to the human body when it digests
the food.

How do we know how much energy is available in food?

We will need to study the ENERGY CHANGES (principally in the
Nutrition label on a pack of rice (UK)
form of the flow of thermal energy or HEAT) that accompany
chemical reactions and processes such as human digestion.

Heat can be released or absorbed during a chemical reaction. In Chemical Energetics, this
heat change is termed the ENTHALPY CHANGE.

1.1 Enthalpy and Enthalpy Change Note:
The lower the
Enthalpy, H, represents the total heat content of a substance or system heat content of
that is held at constant pressure. a substance,
more stable the
What is “heat content”? substance is.

Heat content includes the potential and kinetic energy of particles.
Heat content cannot be measured directly.

What is a “system”?

A “system” is a collection of things that are under study. For example, this can be a sample
of solid (or liquid or gas), or the reactants and products in a reaction mixture.
The “system” is surrounded by space that we call the “surroundings”, and the two are
separated by a “boundary”.

Illustration of system,
SURROUNDINGS boundary and surroundings:
SURROUNDINGS system = reaction mixture in
SYSTEM
beaker; boundary = dotted
BOUNDARY SYSTEM line representing edges of the
BOUNDARY
reaction mixture;
surroundings = beaker and
air.

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For a system which undergoes a chemical reaction, as reactants change to products, there
is an enthalpy change, ∆H, which is the heat absorbed or released in the chemical
reaction, and is given by:

ΔH = H – H
products reactants

Learning Outcome
c) explain and use the term: i) standard conditions

1.1 Standard Conditions

Since enthalpy varies under different temperatures, pressures and physical states of the
reactants and products, an enthalpy change is usually stated under standard conditions;

i.e. standard enthalpy change, ∆Ho.

The superscript o denotes “at standard conditions”.

Standard conditions:

(i) Temperature: 298 K (25 oC)
(ii) Pressure: 1 bar (105 Pa)
(iii) Substance in its most stable physical form
e.g. NaCl(s); H2(g); Br2(l); H2O(l)
(iv) Concentration (when dealing with solutions): 1 mol dm–3

Note:
Standard conditions is NOT standard temperature and pressure (s.t.p.), 273 K, 1 bar!

S.t.p and r.t.p details can be found in the Data Booklet, Section 1 (Important values, constants
and standards). Look for ‘molar volume of gas’.
Standard Room
Standard
Temperature and Temperature and
Conditions
Pressure Pressure
Pressure 1 bar 1 bar 1 atm
Temperature 25 oC 0 oC 20 oC
Substance in its
Additional 1 mole of gas 1 mole of gas
most stable 3
information occupies 22.7 dm. occupies 24.0 dm3.
physical form
Topic in H2
Chemical
Chemistry this is The Mole Concept and Stoichiometry
Energetics
used in

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2. ENTHALPY CHANGE OF REACTION, H
The enthalpy change of a reaction, H, (units: kJ mol–1) is defined as the heat change when
molar quantities of reactants as stated in the chemical equation react together.

Units of H, kJ mol–1

The unit for energy is the joule, J. As values of H are usually rather large, enthalpy
change is expressed in units of kilojoules (kJ), where 1 kJ = 1000 J.

Because this change in energy depends on the number of particles taking part in the
reaction, it is convenient to consider the energy changes associated with one mole of the
reaction equation.

[This is similar to how the “energy value” of a food product is given per 100 g of food (or
sometimes, per serving] Learning Outcome:
Hence the unit of H is in kJ mol–1. (a) Able to identify
exothermic (ΔH,
negative) or
endothermic (ΔH,
positive) energy
2.1 Exothermic and Endothermic Reactions
changes in chemical
Chemical reactions can be classified as either exothermic or endothermic. reactions.

Exothermic Endothermic

Exothermic (Greek: exo means “out”) reaction Endothermic (Greek: “endo” means “in”)
is one which releases heat to the surroundings. reaction is one which absorbs heat from the
surroundings.

System: System:
Heat is Heat is
evolved/ absorbed
released (to Surroundings (from Surroundings
surroundings), gains heat, surroundings), loses heat,
enthalpy temperature enthalpy temperature
decreases. increases increases. decreases

Since heat is released to the surroundings, the Since heat is absorbed from the surroundings,
surrounding temperature increases. the surrounding temperature decreases.

Hence, enthalpy of the system decreases. Hence, enthalpy of the system increases.

H is negative (< 0) H is positive (> 0)
e.g., C(s) + O2(g) → CO2(g) Ho = –393.4 kJ mol–1 e.g., H2(g) + I2(s) → 2HI(g) Ho = +51.9 kJ mol–1

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Chemical Energetics 2024 Semester 1

Learning Outcome:
b) construct and interpret an energy profile diagram, in terms of the enthalpy change of the reaction and of
the activation energy

Energy profile diagrams:
EXOTHERMIC REACTION ENDOTHEMIC REACTION

enthalpy enthalpy

Ea Ea

H1 reactants products
H2
ΔH
H2 products ΔH
H1 reactants
Progress of reaction \
Progress of reaction

H1 = enthalpy of reactants
H2 = enthalpy of products
H = enthalpy change of reaction
= Hproducts – Hreactants
= H2 – H1
Ea = activation energy
(minimum amount of energy reactants must possess for reaction to occur)

A higher enthalpy means a less stable system.

A lower enthalpy means a more stable system.

Therefore, exothermic processes are energetically more favourable than endothermic ones.

2.2 Thermochemical Equations
A thermochemical equation is used to represent the reaction or process being studied
in Chemical Energetics. It is essentially an equation with stoichiometric ratio and its
corresponding H indicated.
Note:
Physical state symbols MUST be given in a thermochemical equation.

The magnitude of H is directly proportional to the amount of reactant consumed in the
process. If we multiply both sides of a thermochemical equation by a factor n, then H
must change by the same factor.
e.g., CH4(g) + 2O2(g) → CO2 (g) + 2H2O(l) Ho = –890.4 kJ mol–1
2CH4(g) + 4O2(g) → 2CO2(g) + 4H2O(l) Ho = 2(–890.4) kJ mol–1

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Worked Example 1

4NH3(g) + 3O2(g) → 2N2(g) + 6H2O(l) Ho = –1260 kJ mol–1

(a) Which has the greater enthalpy, the products or the reactants?
Reactants (because reaction is exothermic)

(b) What is the value of Ho for:
3 1 3
(i) NH3(g) + 4O2(g) → + N2(g) + H2O(l)
2 2
1260
Ho = − = – 315 kJ mol–1
4

(ii) 2N2(g) + 6H2O(l) → 4NH3(g) + 3O2(g)

Ho = +1260 kJ mol–1

Lecture Practice 1
2ZnO(s) + 2SO2(g) → 2ZnS(s) + 3O2(g) Hθ = +890 kJ mol–1

(a) Which has the greater enthalpy, the products or the reactants?

Products (because reaction is endothermic)

(b) What is the value of Ho for
3
ZnS(s) + O2(g) → ZnO(s) + SO2(g) [–445 kJ mol–1]
2

890
Hθ = − = –445 kJ mol–1
2

(c) Write down the thermochemical equation for this reaction for which Ho = +2670 kJ mol–1.

6ZnO(s) + 6SO2(g) → 6ZnS(s) + 9O2(g)

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Chemical Energetics 2024 Semester 1

3. CALCULATION OF ENTHALPY CHANGES, H
There are three main methods of calculating the enthalpy change of a reaction:

Calculation of Enthalpy Changes, H

3.1 Calorimetry 3.2 Bond Energies 3.3 Use of Hess’ Law
(experimental method)
Values obtained The drawing of energy cycles,
Used when ΔT and from Data Booklet. Born–Haber cycles or energy
mass (o volume) are Only used for level diagrams is necessary to
given in the question. simple covalent calculate the enthalpy change
reactants and that cannot be directly obtained
products. by experiment.

Learning Outcome:
d) calculate enthalpy changes from appropriate experimental results, including the use of the
relationship: heat change = mcΔT
3.1 Calorimetry (Experimental Determination of Enthalpy Changes using the
Calorimeter)
The calorimeter is an apparatus used to determine the enthalpy change of a reaction. A simple
calorimeter is shown below:

thermometer

Insulated plastic bottle Reactant B (usually in slight excess to
ensure complete reaction of A)
Reactant A
(amount in moles
accurately measured)

Thinking Question 1:
What is the purpose of insulating the plastic bottle?

To ensure negligible heat loss to or gain from the surroundings (external environment).

Title: Calorimetry
https://youtu.be/EAgbknIDKNo
Duration: watch the video till 2:55 min

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Calculations using experimental results:

Heat change in the reaction

= mass of solution × specific heat capacity of solution × temperature change

= mcT

where: m = mass of the solution (units: g, sometimes given in cm3)
Note:
–1 –1 –3 –1 Sometimes, you
c = specific heat capacity of solution (units: J g K , or J cm K )
may encounter C
Specific heat capacity is the amount of heat required to raise the (capital letter).
C denotes “heat
temperature of 1 g (or 1 cm3) of a substance by 1 K (or 1 oC). capacity” and
has units J K–1.
e.g., 4.18 J g–1 K–1 for water, 2.1 J g–1 K–1 for petroleum.
C = mc
T = temperature change (units can be either K or oC)

Since we define enthalpy change of reaction (Hro) for every one mole of the thermochemical
equation, if we have one mole of limiting reagent in the equation, then we can calculate
enthalpy change of reaction (Hro) as follows:

Hro = enthalpy change of reaction
𝑚𝑐∆𝑇
=± × coefficient of the limiting reagent
no of moles of limiting reagent

HOW TO…
Calculate H from Calorimetric Data
(1) Determine from question, values of m, c, T and n.
Note: T in oC = T in K,
‘m' refers to mass of total aqueous solution (assume solution has a density equal to that of water
= 1 g cm–3), ignore mass of solid for reactions where a solid is added to water or solution.
(2) Calculate heat evolved or absorbed (mcT).
Units will be in J → convert to kJ (Note: 1000 J = 1 kJ)
(3) Calculate the no. of moles (amount) of limiting reagent per equation giving rise to Ho.
(4) Calculate Hro.
 If reaction is exothermic, include ‘–’ sign; If endothermic, include ‘+’ sign.
 If the question states x% efficiency, it means that (100–x)% heat is lost/gained by the
external environment. Hence, divide (mcT) by the efficiency (i.e. x%) to find H.

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Chemical Energetics 2024 Semester 1

Worked Example 2
Thermometer – measures
In an experiment, 2.00 g of powdered zinc is added temperature of surroundings
to 100 cm3 of 0.2 mol dm–3 copper(II) nitrate solution
in an insulated container. The maximum
temperature rise recorded is 5.3 °C.
Calculate the enthalpy change for the reaction:
Zn(s) + Cu2+(aq) → Cu(s) + Zn2+(aq) Surroundings
(specific heat capacity of solution = 4.18 J g–1 K–1; – solution in
Ar of Zn = 65.4) beaker which
is surrounding
Assumptions: System – reaction the reacting
Solution is dilute between Zn and Cu2+ particles
Since density of water = 1 g cm–3, mass of
100 cm3 =100 g
Heat evolved in the reaction is only absorbed
by the water and not anything else
Volume does not change
(1) Determine from question, values of m, c, T and n.
Note: T in oC = T in K, hence T = 5.3 °C (same as 5.3 K)
m = 100 cm3 (same as 100 g); c = 4.18 J g–1 K–1, n to be calculated in step (3)
Recall: ignore mass of solid for reactions where a solid is added to water or solution.

(2) Calculate heat evolved (mcT). Units will be in J → convert to kJ
Heat evolved in the reaction
= mcT
= 100 × 4.18 × 5.3
= 2215.4 J
= 2.22 kJ (Note: 1000 J = 1 kJ) [NO SIGN]

(3) Calculate the no. of moles (amount) of limiting reagent giving rise to H.
2.00
Amount of Zn used = = 0.0306 mol
65.4
100
Amount of Cu2+(aq) used = 0.2 × = 0.0200 mol (limiting)
1000
Hence, n = 0.0200 mol

(4) Calculate Ho
 If reaction is exothermic, include ‘–’ sign; If endothermic, include ‘+’ sign.
𝑚𝑐∆𝑇
 Hro =± × coefficient of the limiting reagent
no of moles of limiting reagent
2.22
= − 0.0200 × 1 = –111 kJ mol–1 (3 sf, sign and units)

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Chemical Energetics 2024 Semester 1

Lecture Practice 2
In an experiment, 100 cm3 of 0.5 mol dm–3 AgNO3(aq) was placed in a plastic bottle.
100 cm3 of 0.5 mol dm–3 KCl(aq) was then added and the mixture stirred. Both solutions were
initially at the same temperature. After mixing, the temperature of the mixture was found to
have risen by 7.5 oC.

Calculate the enthalpy change of the reaction. [–125 kJ mol–1]
(specific heat capacity of solution = 4.18 J g–1 K–1)

AgNO3 + KCl → AgCl + KNO3
Balanced equation for the reaction: ________________________________

(1) Determine from question, values of m, c, T and n.
Note: T in oC = T in K, hence T = ___________
7.5 K
100 + 100 = 200 cm = 200 g ; c = 4.18 J g–1 K–1, n to be calculated in step (3)
3
m = _________________________

(2) Calculate heat evolved (mcT). Units will be in J → convert to kJ

Heat evolved in the reaction = mcT
= (100 + 100) × 4.18 × 7.5
= 6270 J = 6.27 kJ (NO SIGN)

(3) Calculate the no. of moles of limiting reagent giving rise to H.

Amount of AgNO3 used = Amount of KCl used
100
= 0.5 × 1000 = 0.0500 mol

(4) Calculate Hro
 If reaction is exothermic, include ‘–’ sign; If endothermic, include ‘+’ sign.

6.27
 Hro = −
0.05
× 1 = –125 kJ mol–1 (3 sf, sign and units)

Related video:
Title: Energetics Worked Example 3 and 4 learning to use mc delta T
https://youtu.be/2LMWnyqw–vs
Duration: Example 3(a) till 6:05min.
Slight difference: The c value used was 4.20 J g–1 K–1

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Chemical Energetics 2024 Semester 1

(A) Standard Enthalpy Change of Combustion, ΔHco

Learning Outcome
c) explain and use the term: i) enthalpy change of combustion

The standard enthalpy change of combustion, Hco, is defined as the energy released
when one mole of a substance is completely burnt in oxygen under standard conditions of
298 K and 1 bar.

e.g. S(s) + O2(g) → SO2(g) Hco = –297 kJ mol–1 Always
1 mol exothermic!
Hco is always exothermic (negative value), as heat is always evolved in the combustion.

Use of Hco : it gives the energy values of fuels and foods.

Experimental measurements of enthalpy change of combustion can be made in a bomb
calorimeter. A bomb calorimeter is built to withstand high pressures arising due to
combustion in a limited space. The heat released in the reaction heats up a volume of
water in the calorimeter.

If you are interested to find out more:

Title: How a bomb calorimeter works
https://youtu.be/VG9YG0VviHc
Duration: 2:41 min

The typical experimental set–up for schools is as shown below:

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Chemical Energetics 2024 Semester 1

Calculations using experimental results:
Heat change in the reaction
= mass of water × specific heat capacity of water × temperature change
= mcT
Note:
Sometimes, you
where: m = mass of the water heated up (units: g, sometimes given in cm3) may encounter C
c = specific heat capacity of water (units: J g–1 K–1, or J cm–3 K–1) (capital letter).
C denotes “heat
T = temperature change (units can be either K or oC) capacity” and
has units J K–1.
C = mc
Since the thermochemical equation for enthalpy change of combustion is
defined per mole of substance burnt,
mc∆T
enthalpy change of combustion, ∆𝐻𝑐𝜃 = −
no of moles of substance burnt

Note: Enthalpy change of combustion should always be a negative value because the reaction
is always exothermic.

Experimental Limitation of Determination of Hco (Efficiency)
In a combustion reaction, it is unlikely that all the heat released on burning a substance is used
to raise the temperature of water. This is due to heat loss to the surroundings during the
course of experiment (insulation to prevent heat loss is very difficult to carry out). Hence the
value obtained for Hco may be inaccurate and we need to consider the efficiency.

For example, if only 70% of the heat released from the combustion of a substance was
transferred to the water, it is described as 70% efficient.
100 100
Heat released by combustion = heat absorbed by water × = mc∆T ×
70 70

mc∆T 100
Enthalpy change of combustion, ∆𝐻𝑐𝜃 = − ×
no of moles of substance burnt 70

Some assumptions in the calculations:
1. Heat capacity of the calorimeter is negligible (taken to be zero).
i.e. the cup that contains the reaction mixture does not absorb any heat.
2. No gain or loss of heat from the calorimeter to its surroundings.
i.e. the calorimeter is well–insulated.
3. Density and specific heat capacity of the solution is the same as that of water (1.0 g cm −3
and 4.18 J g–1 K–1 respectively). i.e. the solution used must be dilute aqueous solutions.

In reality, the heat capacity of the calorimeter can be determined experimentally. Details of
such an experiment are in Practical Handbook 3, section 4.2.3 Calibration of Calorimeter.

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Worked Example 3

1.80 g of glucose was completely burnt in oxygen. The heat produced was found to raise
the temperature of 5.0 dm3 of water by 1.34 oC.
Calculate the enthalpy change of combustion of glucose.
[Mr of glucose = 180; specific heat capacity of water = 4.18 J K–1 cm–3]

Determine the values of m, c and T and calculate the heat evolved:
Heat evolved in the reaction = mcT
= (5000)(4.18)(1.34)
= 28006 J = 28.0 kJ (NO SIGN)

Calculate the amount of substance burnt:
1.80
Amount of glucose = 180 = 0.0100 mol

Calculate H
28.0
Hco of glucose = − 0.0100 = –2.80  103 kJ mol–1 (3 sf, sign and units)

Lecture Practice 3

Two campers are desperately short of butane fuel, yet they badly need a hot drink. They
estimate that they have 0.05 mol of fuel in their ‘butane gas bottle’.
What is the maximum volume of water (at 20oC) which they could heat to boiling point in order
to make some hot coffee?
[Hco(butane(g)) = –3000 kJ mol–1; specific heat capacity of water = 4.18 J K–1 cm–3]
[449 cm3]
mc∆T
Hco of butane(g) = − = –3000 kJ mol–1
no. of moles of butane burnt

m(4.18)(100–20)
=− 0.05
= − 3000 ×103 (3 sf, sign and units)
m = 449 g
vol = 449 cm3 of water (since the density of water is 1 g cm–3)

In reality, the amount of butane left was not enough to heat the calculated volume of water to
boiling point. Assuming that the campers estimated the amount of fuel correctly, why do you
think this is so?
Heat was lost to the surroundings so not all the heat released was absorbed by the water.

Did you know?
Unlike cars or motorcycles, when airplanes refuel, they almost never fill up to “full tank”. Fuel
is expensive, and the more excess fuel an airplane carries, the more fuel is used (wasted) to
carry the excess weight. The flight engineer is responsible for determining the amount of fuel
to carry on an airplane flight, which depends on the energy released from the combustion of
the fuel, as well as the engine’s ability to convert the energy to mechanical energy (work).

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Chemical Energetics 2024 Semester 1

(B) Standard Enthalpy Change of Neutralisation, Hno
Learning Outcome
c) explain and use the term: i) enthalpy change of neutralisation

The standard enthalpy change of neutralisation, Hno, is defined as the enthalpy change
when one mole of water is formed in the neutralisation between an acid and an alkali, the
reaction being carried out in aqueous solution under standard conditions of 298 K and 1 bar.

e.g. HCl(aq) + NaOH(aq) → NaCl(aq) + H2O(l) Hno = –57.1 kJ mol–1
1 mol Always
exothermic
1 NaOH(aq) + __
__ ½ H2SO4 → __
½ Na2SO4(aq) + H2O(l) Hno = –57.3 kJ mol–1 for strong
1 mol acids and
alkalis!

Hno is always exothermic (negative value) for strong acids and alkalis

Enthalpy change of neutralisation can be measured by mixing solutions of acids and alkalis
in a calorimeter and measuring the rise in temperature.

Experimental Determination of Hno
Because the thermochemical equation for enthalpy change of neutralisation is defined per
mole of water formed,

mc∆T
enthalpy change of neutralisation, ∆𝐻𝑛𝜃 = −
no of moles of water formed

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Chemical Energetics 2024 Semester 1

Thermometer – measures
Worked Example 4 temperature of
surroundings
In an experiment, 100 cm3 of 0.500 mol dm–3 of HCl(aq)
was placed in a plastic beaker.

100 cm3 of 0.500 mol dm–3 NaOH(aq) was then added
and the mixture stirred. Both solutions were initially at the
Surroundings –
same temperature. After mixing, the temperature of the solution in
mixture was found to have risen by 3.4 oC. beaker which is
surrounding the
reacting particles
Calculate the enthalpy change of neutralisation.
[Assume the specific heat capacities of all solutions are
4.18 J g–1 K–1 and that all solutions have a density of
System – reaction
1.0 g cm–3.] between HCl and NaOH

Write a balanced equation for the reaction:
HCl + NaOH → NaCl + H2O

(1) Determine from question, values of m, c, T and n.
Note: T in oC = T in K, hence T = 3.4 K
m = 100 + 100 = 200 cm3 = 200 g; c = 4.18 J g–1 K–1, n to be calculated in step (3)

(2) Calculate heat evolved (mcT). Units will be in J → convert to kJ
Heat evolved in the reaction = mcT
= (100 + 100) × 4.18 × 3.4
= 2842.4 J = 2.84 kJ (NO SIGN)

(3) Calculate the no. of moles of water giving rise to H.
100
Amount of HCl = 0.500 × = 0.0500 mol
1000

100
Amount of NaOH = 0.500 × = 0.0500 mol
1000
There is no limiting reagent as the amounts used are exact.

HCl ≡ NaOH ≡ H2O, hence amount of H2O = 0.0500 mol

(4) Calculate H
2.84
Hno = – = –56.8 kJ mol–1 (3 sf, sign and units.)
0.0500

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Chemical Energetics 2024 Semester 1

Lecture Practice 4

NaOH(aq) + ½ H2SO4(aq) → ½ Na2SO4(aq) + H2O(l)
The standard enthalpy change of the above reaction was determined experimentally by
mixing known volumes of 1.0 mol dm–3 NaOH(aq) and 1.0 mol dm–3 H2SO4(aq). The following
results were obtained:
Volume of NaOH(aq) used = 40.0 cm3 Increase in temperature = 9.0 oC
Volume of H2SO4(aq) used = 20.0 cm3
Use the data given to calculate the standard enthalpy change of neutralisation.
[Assume the heat capacity of all solutions = 4.18 J K–1 cm–3] [–113 kJ mol–1]

(1) Determine from question, values of m, c, T and n.
Note: T in oC = T in K, hence T = ___________
9.0 K
40.0 + 20.0 = 60.0 cm = 60.0 g ; c = 4.18 J K–1 cm–3, n to be calculated in step
3
m = __________________________
(3)

(2) Calculate heat evolved (mcT). Units will be in J → convert to kJ
Heat evolved in the reaction = mcT
= (40.0 + 20.0) × 4.18 × 9.0
= 2257.2 J = 2.26 kJ (NO SIGN)

(3) Calculate the no. of moles of water formed, giving rise to H.
40.0
Amount of NaOH= 1.0 × 1000 =0.0400 mol
20.0
Amount of H2SO4 = 1.0 × 1000 =0.0200 mol
NaOH and H2SO4 react exactly. There is no limiting reagent.
NaOH ≡ ½ H2SO4 ≡ H2O, hence amount of H2O = 0.0400 mol

(4) Calculate Hno
2.26
Hno = − 0.0400 = –56.5 kJ mol–1 (3 sf, sign and units.)

Extension question:
Under the same experimental circumstances, what is the enthalpy change for this reaction:
2NaOH(aq) + H2SO4(aq) → Na2SO4(aq) + 2H2O(l)

2NaOH ≡ H2SO4, and the amount of NaOH = 0.0400 mol
Recall page 5–9:
Hro = enthalpy change of reaction
𝑚𝑐∆𝑇
=± × coefficient of the limiting reagent
no. of moles of limiting reagent
2.26
Hro = − 0.0400 ×2 = − 113 kJ mol–1(3 sf, sign and units.)

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Chemical Energetics 2024 Semester 1

The enthalpies of neutralisation for some strong acids and strong alkalis are given below:

Strong Acid Strong Alkali Hno / kJ mol–1
HNO3 NaOH –57.3
HCl KOH –57.3
HNO3 KOH –57.3

Example: The reaction between HNO3 and NaOH is:
HNO3(aq) + NaOH(aq) → NaNO3(aq) + H2O(l)
HNO3 is a strong acid and NaOH is a strong base and they are fully dissociated
in dilute solutions.
HNO3 → H+ + NO3–
NaOH → Na+ + OH–
Hence, the reaction between any strong acid and any strong base involves simply
the formation of water from H+ and OH– ions.
H+(aq) + OH–(aq) → H2O(l) Hno = –57.3 kJ mol–1
For the neutralisation of strong acids with strong bases, the standard enthalpy change of
neutralisation is almost constant (Hno = –57.3 kJ mol–1).

The enthalpies of neutralisation involving weak acids / weak base are given below:
Weak Strong Hno Strong Weak Hno
Acid Alkali / kJ mol–1 Acid Alkali / kJ mol–1
CH3CO2H NaOH –55.0 HCl NH3(aq) –51.5
HCN NaOH –12.0

If a weak acid or a weak base is used, or if both acid and base are weak, then the
standard enthalpy of neutralisation deviates from –57.3 kJ mol–1.
Reason:
Weak acids and bases only ionise partially in dilute aqueous solution.
e.g. CH3CO2H(aq) ⇌ CH3CO2−(aq) + H+(aq) H > 0
Ionisation, which involves bond–breaking, is an endothermic process. During neutralisation,
some heat released from the neutralisation reaction is absorbed to further ionise the
weak acid/base completely.  Overall, less heat is released.

Hence, for neutralisation reactions involving weak acid and/ or weak base, Hno will be less
exothermic (less negative than –57.3 kJ mol−1) than that of strong acid−strong base
neutralisation reactions.
It is incorrect to say  Hno will be "lower/smaller". It should be "less exothermic".
When H is less exothermic (less negative), less heat is released.

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Chemical Energetics 2024 Semester 1

The actual value for a particular neutralisation will depend on the degree of ionisation of
the weak acid/base.
3.2 Bond Energy (only for covalent bonds)
Learning Outcome:
c) explain and use the term: ii) bond energy (ΔH positive, i.e. bond breaking)

Bond energy (of dissociation) is the energy required to break one mole of a covalent bond
between two atoms in the gaseous state.
Always
e.g. A ⎯ B(g) → A(g) + B(g) Ho > 0 (positive) in kJ mol–1
endothermic!

Energy must be absorbed in order to break a bond between two atoms. Bond–breaking is
an endothermic process.
Energy is released when a bond forms between two atoms. Bond–forming (or bond–
making) is an exothermic process.

Since chemical reactions involve bond–breaking followed by bond forming, the enthalpy
change of a reaction is, therefore, the energy difference between the bond–breaking and
bond–forming processes.

Uses of Bond Energies
1. Bond energies are useful in comparing the strength of covalent bonds.
The greater the bond energy, the stronger the bond.
Very large bond energies can make molecules inert.
e.g. NN molecules are generally unreactive due to the high NN bond energy.

2. Bond energies can also be used to estimate the enthalpy changes of reactions involving
SIMPLE COVALENT MOLECULES. These estimations are particularly useful when
calorimetric or other experimental measurements cannot be made.
The table below shows a list of some bond energies from the Data Booklet:
Bond Energy Bond Energy
Bond Bond
/ kJ per mole of bonds / kJ per mole of bonds
C–H 410 O–O 150
C–C 350 O=O 496
C=C 610 N–N 160
CC 840 NN 944
F–F 158 H–F 562
Cl–Cl 244 H–Cl 431
Br–Br 193 H–Br 366

Bond energies in the Data Booklet used for calculation are merely average bond energy
values and may not be a true reflection of actual bond energies in the molecules.
Thus the enthalpy changes calculated using bond energies are only an approximation.

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Chemical Energetics 2024 Semester 1

HOW TO…
Calculate H using Bond Energies
NOTE: Bond energies can ONLY be USED in reactions involving ONLY SIMPLE COVALENT
MOLECULES!!
(1) Draw structures of the compounds involved. Recall: O2 is O=O; CO2 is O=C=O
(2) List and count the no. of bonds to be BROKEN
(bond–breaking is an endothermic process. Hence put a “+” sign)
(3) List and count the no. of bonds to be FORMED
(bond–forming is an exothermic process. Hence put a “–” sign)
(4) Add up the enthalpy changes from total bonds broken and total bonds formed = Hro

Worked Example 5
Hydrazine is often used as a rocket fuel as it can be stored conveniently as a liquid and it
reacts very exothermically with oxygen forming purely gaseous products.
With reference to the bond energies of the molecules, what is Hro for this reaction per mole
of hydrazine?
N2H4(g) + O2(g) → N2(g) + 2H2O(g) Hro = ?

(1) Draw structures of the compounds involved:

(2) List and count the no. of bonds to be BROKEN (3) List and count the no. of bonds FORMED
bonds broken (endothermic) bonds formed (exothermic)
1 N−N (+160) 1 NN (–944)
4 N−H 4(+390) 4 O−H 4(–460)
1 O=O (+496)
+2216 –2784

(4) Add up the enthalpy changes from total bonds broken and total bonds formed = H
ΔHro = +2216 + (–2784) = –568 kJ mol–1 (3 sf, sign and units.)

Note: Parts (2) to (4) in general is:
ΔHro = sum of all bond energies in reactants – sum of all bond energies in products
(Since B.E. are all positive values in Data Booklet)

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Chemical Energetics 2024 Semester 1

Lecture Practice 5
Calculate Ho for the hydrogenation of ethene.
H H
H H
C C + H H H C C H
H H H H

(1) Structures of the compounds involved have been given.
[–124 kJ mol–1]

(2) List and count the no. of bonds to be BROKEN (3) List and count the no. of bonds FORMED
bonds broken (endothermic) bonds formed (exothermic)
1 C=C (+610) 1 C−C (–350)
4 C−H 4(+410) 6 C−H 6(–410)
1 H−H (+436)
+2686 –2810

(4) Add up the enthalpy changes from total bonds broken and total bonds formed = H

ΔHro = +2686 + (–2810) = –124 kJ mol–1 (3 sf, sign and units.)
Recall: Parts (2) to (4) in general is:
ΔHro = sum of all bond energies in reactants – sum of all bond energies in products
(Since B.E. are all positive values in Data Booklet)

3.3 Use of Hess’ Law
(C) Standard Enthalpy Change of Formation, Hfo

Learning Outcome
c) explain and use the terms: i) enthalpy change of formation

The standard enthalpy change of formation, Hfo, of a substance (usually a compound) is defined
as the enthalpy change when one mole of the substance is formed from its elements under standard
conditions of 298 K and 1 bar. (Elements must be in most stable physical form.)

e.g. H2(g) + ½ O2(g) → H2O(l) Hfo = –268 kJ mol–1
1 mol
If Hfo is exothermic, the substance has lower heat content than its elements and hence,
is energetically more stable than its constituent elements.
Hfo of any element in its normal physical state is zero.
e.g. Cl2(g) → Cl2(g) Hfo = 0

Thinking Question 2:
What enthalpy changes can be used to describe the following equation?
C(s) + O2(g) → CO2(g)

The equation represents the enthalpy change of combustion of C(s) and also the enthalpy
change of formation of CO2(g).

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Chemical Energetics 2024 Semester 1

3.3.1 Hess’ Law

Learning Outcome:
f) apply Hess’ Law to construct simple energy cycles, and carry out calculations involving such cycles
and relevant energy terms

We have seen definitions of various enthalpy changes of reactions so far.

Some can be easily calculated once we do the necessary measurements by conducting
experiments: Hco and Hno. [Refer to Section 3.1(A) and 3.1(B)]

𝑚𝑐∆𝑇 𝑚𝑐∆𝑇
∆𝐻𝑐𝜃 = − ∆𝐻𝑛𝜃 = −
no of moles of substance burnt no of moles of water formed

Some of the enthalpy changes can be calculated by considering the bonds broken and
formed through the use of bond energies [Refer to Section 3.2]

H = sum of all bond energies in reactants – sum of all bond energies in products

(Since B.E. are positive values in Data Booklet)

But…

Many of the other defined enthalpy changes are difficult to find by experimental methods
because the reactions are almost impossible to carry out.

Example: The enthalpy change of formation of carbon monoxide, CO.

C(s, graphite) + ½ O2(g) → CO(g)

The above reaction can never occur alone, as some CO2 will always be
produced at the same time:

C(s, graphite) + O2(g) → CO2(g)

Hence the temperature change measured will never be accurate!

Fortunately we can find such enthalpy changes indirectly, using Hess’ Law.

Hess’ Law states that the enthalpy change of a chemical reaction depends only on the final
and initial states of the system, and is independent of the reaction pathway taken.

This means that the enthalpy change is independent of its path of reaction as long as the
reactants and the products are the same (i.e., same p, T and physical state).

The enthalpy change of a chemical reaction is the SAME whether the change is brought
about in one stage or through intermediate stages.

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 Chemical Energetics 2024 Semester 1

How is Hess’ Law applied?

To apply Hess’ Law, you usually need to construct an energy cycle.

Consider the energy cycle below:

By Hess’s Law, the overall enthalpy change will be the same whether the direct route or
indirect route is used as long as the initial and final states of the system are the same.
By applying Hess’s Law, H1 = H2 + H3

Consider another energy cycle below:

For the indirect route, A and B are first converted to E and F respectively, which then react to
form C.
Given that H for C → E + F is H6, hence H for the reverse reaction E + F → C is −H6.
By applying Hess’s Law, H1 = H4 + H5 − H6

Hess’s Law may not be a representation of actual processes. It is simply an application of
the Law of Conservation of Energy.

Diagrams taken from:
We can draw an energy cycle to find the enthalpy change of reaction based on
Lewis, M.; AS & A

(i) enthalpies of formation: (ii) enthalpies of combustion: Level Chemistry
through diagrams;
Oxford University
Press, 2001

(i) indirect pathway = direct pathway (ii) indirect pathway = direct pathway
Hfo (reactants) + Horeaction = Hfo(products) Horeaction + Hco (products) = Hco (reactants)
rearranging, rearranging,
Horeaction = Hfo (products) – Hfo (reactants) Horeaction = Hco (reactants) – Hco (products)

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Chemical Energetics 2024 Semester 1

HOW TO…
Calculate H using Energy Cycles
(1) Write the chemical equation (with state symbols) asked in the question.
(2) Complete the energy cycle with the other information given from the question.
Some tricks: If Hco values are given, arrows POINT AWAY FROM substance.
If Hfo values are given, arrows POINT TOWARDS compounds.
(refer to energy cycles shown earlier for illustration)
(3) Fill the H values into the cycle.
Note: If no. of moles > 1, you need to multiply the given H value by the correct no. of moles as in
the enthalpy change definition.
Note: Some values may not be given. So you might need to obtain them from Data Booklet, usually IE
and Bond Energy.
(4) Apply Hess’ Law to calculate Hro of the unknown reaction.

A useful formula derived from Hess’ Law for working with enthalpy changes of formation:

Hro = (Sum of Hfo of products) – (Sum of Hfo of reactants)

Worked Example 6
What is the standard enthalpy change of combustion of propyne, C3H4
C3H4(g) + 4O2(g) → 3CO2(g) + 2H2O(l)
given that the standard enthalpy changes of formation of propyne, carbon dioxide and water
are –1258 kJ mol–1, –394 kJ mol–1 and –286 kJ mol–1 respectively?

Energy cycle method:

(1) Write the chemical equation (with state Hco = ?
C3H4(g) + 4O2(g) 3CO2(g) + 2H2O(l)
symbols) asked in the question.

(2) Since Hfo values are given, arrows –1258 0 3(–394) 2(–286)
POINT TOWARDS compounds from
elements. (3) Fill the H values into
3 C(s) + 2 H2(g) + 4 O2(g)
the cycle. (Hfo O2 = 0 kJ mol–1)
Using Hess' Law,
(4) Apply Hess’ Law to calculate Hro Hco + (–1258) + 0 = 3(–394) + 2(–286)
of the unknown reaction.
Hco = 3(–394) + 2(–286) – (–1258)
= –496 kJ mol–1 (3 sf, sign and units.)
Or, using formula above: Hco = [3(–394) + 2(–286)] – [(–1258) + 0] = –496 kJ mol–1

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Chemical Energetics 2024 Semester 1

Lecture Practice 6
Calculate the enthalpy change for the reaction:
CaF2(s) + H2SO4(l) → 2HF(g) + CaSO4(s)
given that the enthalpy changes of formation of CaF2(s), H2SO4(l), HF(g) and CaSO4(s) are
–1220 kJ mol–1, –814 kJ mol–1 , –271 kJ mol–1 and –1434 kJ mol–1 respectively?
[+58.0 kJ mol–1]

Energy cycle method:
Hr = ?
CaF2(s) + H2SO4(l) 2HF(g) + CaSO4(s)

–1220 –814 2(–271) –1434

Ca(s) + F2(g) + H2(g) + S(s) + 2O2(g)

Using Hess’ Law,
Hro = – (–1220 – 814) + 2(–271) + (–1434)
= +58.0 kJ mol–1 (3 sf, sign and units.)

Or, using formula above: Hro = [2(–271) + (–1434)] – [(–1220) + (–814)] = +58.0 kJ mol–1

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Chemical Energetics 2024 Semester 1

Learning Outcome
f) apply Hess’ Law to construct simple energy cycles, particularly:
(i) determining enthalpy changes that cannot be found by direct experiment, e.g. an enthalpy
change of formation from enthalpy changes of combustion

A useful formula derived from Hess’ Law for working with enthalpy changes of combustion:

Hro = (Sum of Hco of reactants) – (Sum of Hco of products)

Worked Example 7
The standard enthalpy change of combustion of graphite is –393.4 kJ mol–1 and that of CO
is –282.9 kJ mol–1.
Calculate the standard enthalpy change of formation of CO.
Energy cycle method:

(1) Write the chemical equation (with state Hfo = ?
C(s) + ½O2(g) CO(g)
symbols) asked in the question.
+ ½O2(g) + ½O2(g)
(2) Since Hco values are given, arrows
–393.4 –282.9
POINT AWAY from substance.
(3) Fill the H values into the cycle. CO2(g)

(4) Apply Hess’ Law to calculate ΔHfo Using Hess’ Law, ΔHfo + (–282.9) = –393.4
of the unknown reaction. ΔHfo = –110.5 kJ mol–1 (3 sf, sign and units.)

Or, using formula above: ΔHfo = –393.4 – (–282.9) = –110.5 kJ mol–1

Lecture Practice 7
The standard enthalpies of combustion of methane, graphite and hydrogen are –890.2 kJ mol–1,
–393.4 kJ mol–1 and –285.7 kJ mol–1 respectively.
Calculate the standard enthalpy change of formation of methane, CH4. [–74.6 kJ mol–1]
Energy cycle method:
Hfo = ?
C(s) + 2 H2(g) CH4(g)

+ O2(g) + O2(g) + 2O2(g)
–393.4 2(–285.7) –890.2

CO2(g) + 2 H2O(l)

Using Hess’ Law, Hfo + (–890.2) = –393.4 + 2(–285.7)
Hfo = –74.6 kJ mol–1 (3 sf, sign and units.)
Or, using formula above: ΔHfo = –393.4 + 2(–285.7) – (–890.2) = –74.6 kJ mol–1

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Chemical Energetics 2024 Semester 1

3.3.2 Other Energy Changes

(D) Standard Enthalpy Change of Hydration, Hhydo
Learning Outcome
c) explain and use the term: i) enthalpy change of hydration

The standard enthalpy change of hydration, Hhydo, of an ion is defined as the enthalpy
change when one mole of the gaseous ions is dissolved in such a large amount of water that
addition of more water produces no further heat change under standard conditions of 298 K
and 1 bar. (i.e. further dilution has no effect) Always
exothermic!
e.g. Na+(g) + aq → Na+(aq) Hhydo = –390 kJ mol–1

Cl– (g) + aq → Cl – (aq) Hhydo = –381 kJ mol–1

Note:
Bond–forming takes place between gaseous ions and water molecules due to ion–
dipole attractions. Since there is no bond–breaking, the enthalpy change is
always exothermic.

hydrated Na+(aq) ion–dipole attractions hydrated Cl–(aq)

Hhydo is always exothermic (negative value), as heat is produced when ion–dipole
attractions are formed between the ions and the dipoles on the water.

The hydration energy of an ion is proportional to the charge density of the ion, i.e. ionic
charge (q) and size (radius, r) of the ion.

𝜃
𝑞
hydration energy, ∆𝐻ℎ𝑦𝑑 ∝
𝑟
The higher the charge and the smaller the size (radius) of the ion, the more exothermic
the hydration energy will be.

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Chemical Energetics 2024 Semester 1

Worked Example 8
The hydration energies for various cations and anions are shown in the following table:

Ion ∆Hhydo / kJ mol–1 Ion ∆Hhydo / kJ mol–1
Na+ –390 Cl– –381
–
Mg 2+
–1891 Br –351
Al 3+ –4613 I–
–307

(a) Why does the hydration energy get progressively less exothermic down the series
Cl–, Br–, I–?

Although they all have the same charge, the ionic size (radius) is increasing from
Cl– to I–. Hence the ion–dipole attractions formed between the ions and water
molecules become increasingly weaker, and thus the hydration energy becomes
less exothermic.

(b) What is the total hydration energy of MgCl2?

Hhyd of MgCl2 = (–1891) + 2(–381)
= –2653 kJmol–1 = –2650 kJmol–1 (3 sf, sign and units.)

Lecture Practice 8
Refer to the table in Worked Example 8.
(a) Why does the hydration energy get progressively more exothermic across the series
Na+, Mg2+ and Al3+?

The ions from Na+ to Al3+ have increasing charges and decreasing ionic size. Hence
the ion–dipole attractions formed between the ions and water molecules become
increasingly stronger, and thus the hydration energy becomes more exothermic.

(b) What is the ionic compound that has the least exothermic hydration energy?
[–697 kJ mol–1]
NaI
Hhyd of NaI = (–390) + (–307) = –697 kJ mol–1 (3 sf, sign and units.)

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Chemical Energetics 2024 Semester 1

(E) Standard Enthalpy Change of Solution, Hsolo

Learning Outcome
c) explain and use the term: i) enthalpy change of solution

The standard enthalpy change of solution, Hsolo, is defined as the enthalpy change when
one mole of a substance is dissolved in such a large volume of solvent that addition of more
solvent produces no further heat change under standard conditions of 298 K and 1 bar. (i.e.
further dilution has no additional effect.)

e.g. NaCl(s) + aq → Na+(aq) + Cl–(aq) Hsolo = = + 3.9 kJ mol–1

NH3(g) + aq → NH3(aq) Hsolo = –35.2 kJ mol–1

Hsolo can be exothermic or endothermic (negative or positive values).

Despite its common reference to ionic compounds, standard enthalpy change of solution
is also defined for covalent compounds (such as ethanol or sugar), and gases (such as
carbon dioxide or ammonia).

(Refer to Chemical Bonding for more information on the process of dissolution.)

Did you know?
Instant cold packs can be used to treat fever, burns, and swelling due to
bruises. They are useful in situations such as outdoor camping or trekking,
where ice is not readily available. How do instant cold packs work?

Many cold packs contain ammonium nitrate as the active ingredient. The
enthalpy change of solution of ammonium nitrate is endothermic:
NH4NO3(s) + aq → NH4+(aq) + NO3–(aq) Hsolo = +25.4 kJ mol–1
In instant cold packs, a sachet of ammonium nitrate solid is sealed inside
a bag of water. Hitting the cold pack breaks the sachet, causing the ammonium nitrate to mix
with and dissolve in the water. Since the dissolution of ammonium nitrate is endothermic, heat
is absorbed from the surroundings and the pack becomes cold.

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Chemical Energetics 2024 Semester 1

Energy Changes Involving Aqueous Solutions of Ionic Compounds
Learning Outcome:
f) apply Hess’ Law and carry out calculations with particular reference to:
(ii) the formation of a simple ionic solid and of its aqueous solution

When sodium chloride dissolves in water, the following process occurs:

Na+Cl–(s) + aq → Na+(aq) + Cl–(aq) Hsolo

We can see how the enthalpy terms: lattice energy and Hhydo are related to Hsolo
by constructing the following energy cycle:

Solid ionic Hsolo Aqueous Recall:
compound ions Lattice energy
is the energy
evolved when
lattice energy one mole of
Hhydo ionic solid is
formed from
Gaseous
its separate
ions gaseous ions.

By Hess’ Law, Hsolo = – lattice energy + ΣHhydo

Using NaCl to illustrate:
Hsolo
NaCl (s) Na+(aq) + Cl–(aq)

lattice energy Hhydo
Na+(g) + Cl–(g)

Diagrammatically, we can see how the processes are related:

Diagram modified
from JGR Briggs,
Longman ‘A’ Level
Course in
Chemistry,
Longman 2005

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Chemical Energetics 2024 Semester 1

In general,

if Hhydo > lattice energy (in magnitude) then Hsol is negative, the salt likely dissolves
readily in water.
If Hhydo < lattice energy (in magnitude) then Hsolo is positive, the salt may be
relatively insoluble. (This may not always be true and Gsolo (see 4.2) has to be
considered)
Worked Example 9

Draw an energy cycle relating the following enthalpy changes for magnesium chloride:

Hsolo (MgCl2) = –132 kJ mol–1

Hhydo (Mg2+) = –1921 kJ mol–1

Hhydo (Cl–) = –364 kJ mol–1

Lattice energy of magnesium chloride
Hence, calculate the lattice energy of magnesium chloride.

Lattice energy
Mg2+(g) + 2Cl–(g) MgCl2(s)

–1921 + 2(–364) –132
Mg2+(aq) + 2Cl–(aq)

By Hess’ Law, Lattice energy = –1921 + 2(–364) – (–132)
= –2517 = –2520 kJ mol–1 (3sf, sign and units)

Lecture Practice 9

Draw an energy cycle relating the following enthalpy changes for iron(III) chloride:

Hsolo (FeCl3) = –928 kJ mol–1

Hhydo (Fe3+)

Hhydo (Cl–) = –364 kJ mol–1

Lattice energy of iron(III) chloride = –3865 kJ mol–1

Hence, calculate the enthalpy change of hydration of Fe3+. [–3700 kJ mol–1]

–928
FeCl3(s) Fe3+(aq) + 3Cl–(aq)
Hhydo 3(–364)
–3865 3+ –
Fe (g) + 3Cl (g)

By Hess’ Law, –3865 – 928 = Hhydo (Fe3+) + 3(–364)
Hhydo (Fe3+) = –3701 kJ mol–1 = –3700 kJ mol–1 (3 sf, sign and units)

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(F) Lattice Energy (Revision: Chemical Bonding)
Learning Outcome:
c) explain and use the term: (iii) lattice energy (H negative, i.e., gaseous ions to solid lattice)
e) explain, in qualitative terms, the effect of ionic charge and of ionic radius on the numerical
magnitude of a lattice energy

It is very important not to confuse bond energy with lattice energy. Bond energy can only be
used for covalent bonds, whereas lattice energy can only be used for ionic compounds.

What is lattice energy?

The ions in an ionic crystal are bound together by electrostatic attractive forces between
the ions and there is a considerable release of energy when such a crystal is formed.

e.g., Na+(g) + Cl–(g) → NaCl (s) H = lattice energy

The lattice energy of an ionic solid is the energy evolved when one mole of the ionic solid
is formed from its separate gaseous ions.

e.g., K+(g) + Cl–(g) → KCl(s) Ho = –701 kJ mol–1
Always
All lattice energies are exothermic (negative values) because heat is evolved exothermic!

when the ions come together to form ionic bonds.

What is the physical significance of lattice energy?

It provides a measure of the attractive force holding the ions in their positions in a crystal
lattice, i.e., it provides a measure of the strength of the ionic bonds.

The more exothermic the lattice energy, the stronger the ionic bond strength.

Factors affecting the magnitude of lattice energy:
q+ q–
since lattice energy 
r+ +r–

(q+ = charge on cation, q− = charge on anion, r+ = cationic radius, r− = anionic radius)

Recall:

The higher the charges on the ions, the more exothermic the lattice energy.

The smaller the radii of the ions, the more exothermic the lattice energy.

The arrangement of the ions in the crystal (crystal structure) also affects the magnitude of
the lattice energy, but this effect is small.

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Worked Example 10
Explain why the melting point of MgO is higher than that of CaO.

Both MgO and CaO have giant ionic structures.
Both Mg2+ and Ca2+ have the same ionic charge, however Mg2+ is smaller than Ca2+.
Hence, the lattice energy of MgO is more exothermic / greater in numerical
magnitude than CaO.
More energy is required to break the stronger ionic bonds between Mg2+ and O2– as
compared to the energy required for Ca2+ and O2–.
Therefore MgO has a higher melting point than CaO.

Lecture Practice 10
Which of the following compounds would have the largest lattice energy in magnitude?
Na2O MgO NaCl MgCl2
Explain your choice.
q+ q–
Using lattice energy  ,
r+ +r–

Mg2+ has a higher charge than Na+, and O2– has higher charge than Cl–.
Mg2+ is smaller than Na+, and Cl– is smaller than O2–.
(Charge is the more dominant factor affecting lattice energies, if ions concerned are
from same period.)
Ans: MgO would have the largest lattice energy in magnitude.
Theoretical and Experimental Lattice Energy
Theoretical calculation of lattice energies assumes that compounds are purely ionic. The
table below shows some comparisons:
Calculated L.E. / Difference as
Observed L.E.
kJ mol–1 a % of
/kJ mol–1
Compound (theoretical, purely Difference observed
(experimental)
ionic) value
NaCl –776 –786 10 1.3
NaBr –733 –744 11 1.5
NaI –684 –697 13 1.9
AgCl –768 –890 122 15.9
AgBr –759 –877 118 15.5
AgI –736 –867 131 17.8
Observations:
Slight discrepancies between the theoretical and experimental lattice energies for NaCl, NaBr, NaI. This close
agreement provides strong evidence in favour of the ionic model i.e. alkali metal halides form ionic crystals with
little or no covalent character.
Large discrepancies between the theoretical and experimental lattice energies for AgCl, AgBr, AgI. This difference
is attributed to polarisation of the halide ions i.e. silver halides form ionic crystals with a considerable percentage
of covalent character.

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(G) Standard Enthalpy Change of Atomisation Hato

Learning Outcome
c) explain and use the term: i) enthalpy change of atomisation

The standard enthalpy change of atomisation, Hato, is defined as the enthalpy change
when one mole of separate gaseous atoms is formed from its element under standard
conditions of 298 K and 1 bar.

e.g. Na(s) → Na(g) Hato = +108 kJ mol–1
1 mol

½ H2(g)
___ → 1 H(g)
___ Hato = +218 kJ mol–1
1 mol Always
endothermic!

I. Hato is always endothermic (positive value), because energy must be absorbed to pull
the atoms far apart and to break all the bonds between them.

II. The enthalpy change of atomisation is not the same as the enthalpy change of
vaporisation.

Note:
Enthalpy change of atomisation involves the breaking of intramolecular bonds as well.
Enthalpy change of vaporisation involves only the breaking of intermolecular bonds,
i.e. a change of state.
Br2(l) → Br2(g)
Hence when an element is vaporised, the gas particles are usually not separate atoms.

III. For all noble gases (e.g., Ne, Ar), the enthalpy change of atomisation is zero. This is
because the elements are already in the form of separate gaseous atoms under
standard conditions.

IV. For simple gaseous diatomic molecules, Hato = ½ Bond Energy

Example using chlorine gas: Hato is given by ½ Cl2(g) → Cl(g)

Bond Energy is given Cl2(g) → 2Cl(g)

Thinking Question 3:
Would Hato of Br2 = ½ Bond Energy of Br2?

No. Br2 is a liquid under standard conditions.
Hence Hato of Br2 = Hvapo of Br2 + ½ Bond Energy of Br2

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(H) Ionisation Energy (Revision: Atomic Structure)
Ionisation energy (I.E.) is the energy required to remove one mole of electrons from one
mole of gaseous atoms (or ions) to produce one mole of gaseous cations. Always
endothermic!

I.E. is always endothermic (positive value) since energy is absorbed in ionisation.

The successive ionisation energies of an element increase with removal of each electron
because the remaining electrons are attracted more strongly (due to less shielding effect)
to the constant positive charge on the nucleus.
e.g. X(g) → X+(g) + e– H1 = 1st I.E. of X(g)
X (g) → X (g) + e
+ 2+ –
H2 = 2nd I.E. of X(g) (>H1)

The energy needed to ionise one mole of X(g) atoms to its divalent ions
(i.e. X(g) → X2+(g) + 2e–) = H1 + H2

Thinking Question 4:
What is the definition of the second ionisation energy?
Energy required to remove one mole of electrons from one mole of gaseous X+
cations to form one mole of gaseous X2+ cations.

(I) Electron Affinity
The electron affinity of an element is the energy change when one mole of electrons is added
to one mole of gaseous atoms to produce one mole of gaseous anions.

e.g. Cl(g) + e– → Cl–(g) Ho = –364 kJ mol–1 (first electron affinity)

It is a measure of the attraction of the atom for additional electrons.
The first E.A. of an element is usually exothermic (negative value) as the incoming electron
is attracted to the nuclear charge of the atom.

Thinking Question 5:
Would you expect the 2nd electron affinity of O to be exothermic or endothermic? Why?
O–(g) + e– → O2–(g)

For second EA, energy is always absorbed (endothermic) because the incoming second
electron must overcome the repulsion from the (negatively charged) anion.

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3.3.3 Born–Haber Cycle
Learning Outcome:
f) apply Hess’ Law to construct simple energy cycles, e.g., Born–Haber cycle, and carry out
calculations involving such cycles and relevant energy terms (including ionisation energy and
electron affinity)
The Born–Haber Cycle is an energy cycle commonly used to calculate the lattice energy
of an ionic solid as lattice energy cannot be directly measured.
The cycle gives the relationship between the standard enthalpy change of formation of the
ionic solid and the various enthalpy changes leading to its formation.
When the various enthalpy changes and lattice energy are put in a cycle, it may appear
something like this:
Gaseous ions

IE, EA
Hlatto (Lattice Energy)
Gaseous atoms

Hato, BE
Hfo
elements solid ionic compound

Worked Example 11

Lattice energies are not measured directly. By using Hess' Law and the Born–Haber cycle,
they can be obtained from experimental data. Construct a Born–Haber cycle which can be
used to calculate the lattice energy of sodium chloride.

Draw arrows representing the energy changes involved, and label them clearly. Use words
and symbols to represent these energy terms.
By Hess’ Law,
–
Na+ (g) + Cl (g) Hfo = H1o + H2o + H3o + H4o + H5o

H3o H4o
H5o where
Na(g) + Cl(g) H1o = enthalpy change of atomisation of Na
H2o = enthalpy change of atomisation of Cl
H1o H2o H3o = first ionisation energy of Na
Hfo
Na (s) + ½ Cl2(g) NaCl (s) H4o = first electron affinity of Cl
H5o = lattice energy of NaCl

Title: Energetics Lecture 2013 How to draw a BH Cycle
https://youtu.be/pqBGu2LEbbU
Duration: 5:55 min (Lecturer: Mrs Angela Tie)

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HOW TO…
Draw a Born–Haber Cycle
1. Anchor the Born–Haber cycle with two H equations: Hf o & Hlatt o of the ionic compound.
e.g., Hf o of NaCl (s) & Hlatt o of NaCl :
Hf o of NaCl (s): Na(s) + ½ Cl2(g) → NaCl (s)
Hlatt o of NaCl (s): Na+(g) + Cl–(g) → NaCl (s)

2. Connect the two equations.
3. Complete the cycle by filling in the remaining H (moving from elements → ionic compound)
4. Fill in the H values from data given.
Note: Some values may not be given. So you might need to obtain them from Data Booklet, usually IE and Bond
Energy.

5. Apply Hess’ Law to calculate H of the unknown reaction

Lecture Practice 11
By drawing a Born–Haber cycle, calculate the lattice energy of calcium fluoride given the
following information:

H / kJ mol–1
Enthalpy change of atomisation of calcium +184
Enthalpy change of atomisation of fluorine +79
First ionisation energy of calcium +590
Second ionisation energy of calcium +1150
Electron affinity of fluorine –328
Enthalpy change of formation of calcium fluoride –1220
[–2650 kJ mol–1]
Born–Haber Cycle for formation of CaF2
Ca2+(g) + 2 F–(g)

+1150
Ca+(g) 2(–328)
H = ?
+590
Ca(g) 2 F(g)

+184 2(+79)
–1220
Ca(s) + F2(g) CaF2(s)

By Hess’ Law, –1220 = 184 + 2(79) + 590 + 1150 + 2(–328) + H
H = –2646 kJ mol–1 = –2650 kJ mol–1 (3 sf, sign and units)

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3.3.4 Energy Level Diagram
Alternatively, the reactions making up the Born–Haber cycle can also be represented using
an energy level diagram. Unlike the Born–Haber Cycle, the energy level diagram must have:

1 y–axis representing energy
2 A datum line if elements are involved. A datum line is the arbitrary zero enthalpy content
of any pure element. (I.e. Pure elements in their standard states are defined as having
zero enthalpy content)
3  arrows for endothermic reaction (+ve) and  arrows for exothermic reaction (–ve). It
will be useful to note that:
Standard enthalpy change of formation of ionic compound: 
Standard enthalpy change of atomization of metal: 
Standard enthalpy change of atomization of non–metal: 
Ionisation energy of metal: 
Electron affinity of non–metal: usually 1st E.A.  and 2nd E.A. 
Lattice energy: 
Example: For an ionic compound, MX, the energy level diagram looks like this:

energy M+ (g) + e– + X (g)

1st IE (M) 1st EA (X)

M+ (g) + X– (g)
M (g) + X (g)

Hato (X) = ½ BE(X–X)

M (g) + ½ X2 (g)
Hlatto (MX)
Hato (M) Each change in
level represents
M (s) + ½ X2 (g) only 1 chemical
0 change, i.e., no
Hf o (MX) “parallel” changes
are allowed.

MX (s)

Hess’ Law can be applied to energy level diagrams as well.
For example, in the above diagram,
Sum of H in clockwise direction = Sum of H in anticlockwise direction
Hf o (MX) = Hato (M) + Hato (X) + 1st IE (M) + 1st EA (X) + Hlatto (MX)

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An energy level diagram for the formation of NaCl:

Energy
Na+(g) + Cl(g)

Ho3
Na(g) + Cl (g) o Ho4
o
Ho2o Na+(g) + Cl–(g)
Na(g) + ½ Cl2(g)

Ho1
0
Na(s) + ½ Cl2(g) o Ho5o
Hof
NaCl (s)

Energy level diagrams can be drawn in place of all types of energy cycles. For example,
enthalpy changes involving aqueous ionic compounds:

Energy
Na+(g) + Cl–(g)

Hohyd
Na+(aq) + Cl–(aq) Holatto
Hosol
NaCl (s)

In the above diagram, there is no datum line as pure elements are not involved. Note here that
Hosol for NaCl(s) is endothermic, thus aqueous NaCl has higher enthalpy than NaCl(s) and
so the Hosol arrow points upwards.

Hosol for many other ionic compounds such as KCl(s) is exothermic, however, so the aqueous
solution has a lower enthalpy than the ionic solid, resulting in the energy level diagram below:

Energy

K+(g) + Cl–(g)

Hohyd Holatt
KCl (s)
Hosol
K+(aq) + Cl–(aq)

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Lecture Practice 12
Fill in the blanks in the energy level diagram with the names of the appropriate enthalpy
changes, e.g. lattice energy, including coefficients if necessary.

Energy

Al3+(g) + 3F(g) + 3e–

Al (g) + 3F(g) (c)
(d)

3 (b) Al3+(g) + 3F–(g)
Al (g) + 2
F2(g)

3 (a)
Al (s) + 2
F2(g) lattice
0
energy
Hof = ‒1510 kJ mol–1

AlF3 (s)

(a) Hatmo (Al)

3
(b) 3 Hatmo (F2) = BE (F2)
2

(c) 1st IE + 2nd IE + 3rd IE of Al

(d) 3 x 1st EA of F

Calculate the lattice energy of aluminium fluoride using the following data any other data that
can be obtained from the Data Booklet.
enthalpy change of atomisation of aluminium = +326 kJ mol‒1
first electron affinity of fluorine = ‒328 kJ mol‒1

Sum of H in clockwise direction = Sum of H in anticlockwise direction
3
‒1510 = +326 + 2(158) + 577 + 1820 +2740 + 3(‒328) + Hlatto (AlF3(s))
Hlatto (AlF3(s)) = ‒6226 kJ mol–1
= ‒6230 kJ mol–1 (3 sf, sign and units)

[‒6230 kJ mol–1]

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SUMMARY OF METHODS TO FIND ENTHALPY CHANGE
3.1 Calorimetry (experimental method)
Used when ΔT and mass are given in the question.

Relevant formulae:
𝑚𝑐∆𝑇 𝑚𝑐∆𝑇
∆𝐻𝑐𝜃 = −