Grade 11: Unit 6- Energetics

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Grade 11: Unit 6- Energetics

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Title: Grade 11: Unit 6- Energetics

1
IB Chemistry HL1

Grade 11 Unit 6- Energetics
IB Topic 5

2
System and Surroundings

The system is the name we give the sample or
reaction vessel of interest.
The surroundings are everything else in the
universe.
When a chemical change happens in an open system
matter and energy can be exchanged between the
system and the surroundings.
In a closed system only energy can be exchanged
with the surroundings.

3
System and Surroundings
4
Energy

Energy is defined as the ability to do work.
Energy is often converted from one form to
another during physical and chemical changes.
Thermochemistry is the study of energy changes
associated with chemical reactions.
Chemical energy is the energy stored in chemical
bonds. It is a type of potential energy.

5
Thermochemistry

Most reactions absorb or evolve energy usually in
the form of heat but chemical reactions can also
produce light, electricity and mechanical energy
used to do work.
Energy is measured in joules, J.
1000 J 1 kJ.
Physical changes like change of state/phase also
have heat energy changes.

6
Exothermic and Endothermic Reactions

5.1.1 Define the terms exothermic reaction,
endothermic reaction and standard enthalpy change
of reaction (?H).
Standard enthalpy change is the heat energy
transferred under standard conditionspressure
101.3 kPa, temperature 298 K. Only ?H can be
measured, not H for the initial or final state of
a system.

7
Exothermic and Endothermic Reactions

5.1.3 Apply the relationship between temperature
change, enthalpy change and the classification of
a reaction as endothermic or exothermic.
5.1.4 Deduce, from an enthalpy level diagram, the
relative stabilities of reactant and products,
and the sign of the enthalpy change for the
reaction.

8
Enthalpy

Enthalpy is the total energy of a system, some of
which is stored as chemical potential energy in
the chemical bonds.
Enthalpy is given the symbol H.
Enthalpy is also known as the heat content of a
system.
We cannot measure the enthalpy content of a
system but we can measure changes in it.

9
Enthalpy Change

In chemical reactions, bonds are broken and made,
but the energy absorbed breaking bonds is almost
never exactly equal to that released in making
new bonds.
All reactions are accompanied by a change in the
potential energy of the bonds and hence an
ENTHALPY CHANGE.
There is no absolute zero for enthalpy so
absolute enthalpies cannot be measured only the
change in enthalpy that occurs during a reaction.

10
Enthalpy Change

The enthalpy change of a reaction is given the
symbol ?H.
?H is the difference in the enthalpy between the
products and the reactants.
?H H(products) - H(reactants) when at constant
pressure.
Enthalpy level diagrams are used to show the
change in enthalpy of a system during a change.

11
Enthalpy Level Diagram
12
Enthalpy Level Diagram
13
Endothermic Reaction

An endothermic reaction is one where energy is
transferred from the surroundings to the system.
If energy is absorbed during a reaction then the
enthalpy of the products will be higher than that
of the reactants.
This means the enthalpy change will have a
positive sign.
This reaction will either get cooler or heat will
need to be supplied - temperature decreases.

14
Exothermic Reaction

An exothermic reaction is one where energy is
transferred from the system to the surroundings.
If energy is released during a reaction then the
enthalpy of the products will be lower than that
of the reactants.
This means the enthalpy change will have a
negative sign.
This reaction will feel hotter - temperature
increases.

15
Stability

Reactions in chemistry tend towards products that
are more stable.
Stability increases as energy decreases so
exothermic reactions increase the stability of
the substances.
This is why most chemical reactions that occur in
nature are exothermic.
Endothermic reactions usually need help in the
form of energy to allow them to occur.

16
Stability

Remember that lower energy is more stable. We can
compare this to standing on top of a high
building where you have more potential energy
than someone on the ground.
If you fall to the ground you lose some of that
potential energy you had on the roof but you are
now more stable.

17
Exothermic and Endothermic Reactions

5.1.2 State that combustion and neutralization
are exothermic processes.

18
Combustion

Combustion is the scientific word for burning.
Most hydrocarbons burn easily in excess oxygen.
When they burn they produce carbon dioxide and
water.
Ex. CH4(g) 2O2(g) ? CO2(g) 2H2O(g)
Combustion produces lots of heat which is
transferred to the surroundings so it is very
EXOthermic.

19
Combustion

When 1 mole of a substance is burned the energy
released is called the Enthalpy Change of
Combustion, ?Hc.
The sign indicates this was measured under
standard conditions in a controlled environment.
Standard conditions for thermochemistry
experiments are T 298K and P 101.3kPa ( 1
atm).

20
Neutralization

Neutralization reactions involved acids and
bases.
If an acid and a base react completely the
resulting solution will be pH neutral.
The products are a salt (ionic compound) water.
Ex. NaOH(aq) HCl(aq) ? NaCl(aq) H2O(l)
When weak acids and bases are involved such as
NaHCO3 then CO2(g) may be another product.
These reactions release energy to the
surroundings so they are EXOthermic.

21
Negative ?H

As combustion and neutralization reactions are
always exothermic the enthalpy changes will
always have negative values.
You can find many ?H values in scientific
literature ex. your textbook, the books in the
classroom and online.

22
Spontaneous Reactions

A spontaneous reaction is one that occurs when
the reactants are mixed without the need to be
heated or have some other outside influence.
Most spontaneous reactions are EXOthermic but
there are some spontaneous endothermic reactions
ex. Dissolving NH4Cl in water.

23
Summary of Enthalpy Changes
24
Enthalpy Changes

In an exothermic reaction the products are more
stable than the reactants so the bonds made are
stronger than the bonds broken.
In an endothermic reaction the products are less
stable than the reactants so the bonds made are
weaker than the bonds broken.

25
Enthalpy Changes

Enthalpy changes are usually written alongside
the chemical equation for the process with a
positive or negative sign.
State symbols are VERY IMPORTANT as changes of
state have their own enthalpy change values.
Enthalpy changes are usually reported per mole so
the units are kJ mol-1.
If this is not the case then just kJ is used.

26
Enthalpy Changes

For example
2NaHCO3(s) ? Na2CO3(s) H2O(l) CO2(g)
?H 91.6 kJ mol-1
The sign indicates its an endothermic reaction.

27
Standard Conditions

To compare enthalpy changes conditions must be
the same.
The thermochemical standard conditions are
Temperature 25C 298K (this is room temp)
Pressure 1 atm 101.3kPa
Solutions have a concentration of 1 mol dm-3
Standard conditions are sometimes indicated by
the symbol ? or ?H? or?H
Sometimes the temperature is included too ?H?
298.
The values in bold are the SI units.

28
Learning Check Do NOW

Write the equation for the formation of chlorine
oxide, Cl2O from its elements
What bonds are broken and what bonds are made in
this process?
Do the processes in 2. absorb or release energy?
What is an enthalpy change?
In this reaction the bonds made are less strong
than those broken. Will the enthalpy change be
positive or negative?
Will this be an exothermic or endothermic
reaction?

29
Calculation of Enthalpy Changes

5.2.1 Calculate the heat energy change when the
temperature of a pure substance is changed.
Students should be able to calculate the heat
energy change for a substance given the mass,
specific heat capacity and temperature change
using q mc?T.
5.2.2 Design suitable experimental procedures for
measuring the heat energy changes of reactions.
Students should consider reactions in aqueous
solution and combustion reactions.

30
Calculation of enthalpy changes

5.2.3 Calculate the enthalpy change for a
reaction using experimental data on temperature
changes, quantities of reactants and mass of
water.
5.2.4 Evaluate the results of experiments to
determine enthalpy changes. Students should be
aware of the assumptions made and errors due to
heat loss.

31
Temperature

Temperature is a measure of the average kinetic
energy of the particles in a system.
Units are K or C.
Note there is no sign used with K!
Heat is a measure of the total energy in a
substance.
TC 273 TK
TK 273 TC

32
Specific Heat Capcity

Some substances will conduct heat and therefore
change temperature more easily than others.
Ex. A metal pan on a stove will become very hot
before the water inside it does.
A measure of how easily something changes
temperature is called SPECIFIC HEAT CAPACITY.

33
Specific Heat Capacity

Specific heat capacity is the amount of heat
energy required to increase 1 g of a substance by
1K or 1C.
It is used in the following equation
q m x c x ?T where q is heat energy, m is mass,
c is specific heat capacity and ?T is change in
temperature.

34
Specific Heat Capacity

Units of specific heat capacity (c) are J g-1K-1
Units of heat energy (q) are J or kJ
Units of mass (m) are g or kg
Units of temperature (T) are K or C

35
Calorimetry

Calorimetry is a method used to measure the
enthalpy associated with a particular change.
The temperature change of a liquid is measured
inside a well insulated container called a
calorimeter.
Often a styrofoam cup is used as it has a very
low heat capacity and is a good insulator.

36
Measuring Energy Changes

To measure the enthalpy change of a reaction that
occurs in solution you can carry it out in a
styrofoam (polystyrene) cup and monitor the
temperature during the reaction.
Styrofoam is a good insulator so the amount of
heat lost to the surroundings will be reduced.

37
Measuring Energy Changes

Burning substances in a bomb calorimeter
measures the temperature change in the water
surrounding the burning item.
This system is also well insulated to try and
reduce heat loss.
There may be some losses from incomplete
combustion.

38
Calorimetry

If calorimeters made of other materials are used
then the heat absorbed by the calorimeter must be
added to that absorbed by the liquid
Heat absorbed (mc?T)liquid (mc?T)calorimeter
Calorimetry assumes no heat is transferred to or
from the surroundings so they must be well
insulated.
However this is hard to achieve and is a major
source of error in high school labs.

39
Calorimetry

Once you have calculated the energy released from
a process then you can calculate how many kJ of
energy were released per mole of the reactant.
This is usually referred to as ?H or molar
enthalpy in a test question.
?H q/n
Where n represents the number of moles of the
reactant that is reacting/burning.

40
Sample Problems

Specific heat, c of liquid water 4.18 kJ
dm-3K-1
4.18J g-1K-1
How much heat energy is required to increase the
temperature of 10 g of nickel (c 440 J g-1K-1)
from 50C to 70C?
The enthalpy of combustion of ethanol (C2H5OH) is
1370 kJ mol-1. How much heat is released when
0.200 mol undergo complete combustion?

41
Sample Problems

3. H2(g) 1/2 O2(g) ? H2O(l)
?H for the reaction above is -286 kJ mol-1. What
mass of oxygen must be consumed to produce 1144
kJ of energy?
4. Calculate the molar enthalpy change when
excess zinc is added to 50 cm3 of a 1 mol dm-3
solution of CuSO4. The temperature increases from
20C to 70C when the zinc is added. Assume the
solution has the same density as water 1.00 g
cm-3

42
Bond Enthalpies

5.4.1 Define the term average bond enthalpy.
5.4.2 Explain, in terms of average bond
enthalpies, why some reactions are exothermic and
others are endothermic.

43
Bond Enthalpies

All chemical reactions involve the making and
breaking of bonds.
The bonds in the reactants are broken which
absorbs energy so this is an endothermic process.
The bonds in the products form which releases
energy so this is an exothermic process.

44
Bond Enthalpy

Bond enthalpy is defined as the energy needed to
break one mole of bonds in gaseous molecules
under standard conditions.
Ex. ½ H2(g) ½ Cl2(g) ? H(g) Cl(g)
Breaking a bond is endothermic so these values
are always positive.
Bond enthalpies depend on the rest of the
molecule so values are usually averages.

45
Bond Enthalpy

The energy released when a bond is made is the
same value as the bond enthalpy but with a
negative sign.
A higher bond enthalpy indicates a stronger bond.

46
Bond Enthalpy

If the bonds being broken (bonds in the
reactants) are weaker than those being made
(bonds in products) then the reaction will be
exothermic.
If the bonds being broken are stronger than those
being made then the reaction will be endothermic.

47
Bond Enthalpies

As bond enthalpies are averages and they are only
for gases they are not the most accurate way to
calculate an enthalpy change but they are usually
within about 10 of more accurate values and are
a useful tool.
?Hºreaction ?BEbonds broken- ?BEbonds made
Where BE stands for bond enthalpy

48
Bond Enthalpy

Bond enthalpy values are given in the data
booklet. A sample is shown here. When using these
values be careful to check if bonds are single or
double etc.

Bond E / kJ mol-1
H-H 436
C-H 413
C-C 347
CC 612
OO 498
49
Bond Enthalpy Calculations

When water is formed from its elements, what
bonds are broken and formed? What is the enthalpy
change predicted by bond enthalpies?
2H2(g) O2(g) ? 2H2O(l)
Bonds broken 2(H-H), 1 (OO)
Bonds formed 4 (O-H)
?H Sbonds broken Sbonds formed

50
Bond Enthalpy Calculations

(2(436) 498 ) (4(464))
(872 498) (1856)
1370 1856 -486 kJ
What does this sign tell you about the reaction?
Does this make sense?

51
Practice Problem

Find the enthalpy change when CO2(g) is formed
from its elements using bond enthalpy values in
the data booklet.

52
Hesss Law

5.3.1 Determine the enthalpy change of a reaction
that is the sum of two or three reactions with
known enthalpy changes.
Students should be able to use simple enthalpy
cycles and enthalpy level diagrams and to
manipulate equations. Students will not be
required to state Hesss Law.

53
Hesss Law

Hesss Law is a special case of the law of
conservation of energy.
It states that the enthalpy change for a reaction
will have the same value no matter how many steps
were taken to go from reactants to products.
Another way we can use it is to say the enthalpy
change for the reaction is equal to the enthalpy
of the products - enthalpy of reactants.

54
Hesss Law

Hesss Law enables us to calculate an enthalpy
change for a reaction without carrying out the
actual reaction.
We do this by measuring the enthalpy change for
other related reactions.
Hesss Law is very useful for reactions that are
difficult to carry out in a lab or that do not
occur.

55
Hesss Law

For example sodium hydrogen carbonate can be
reacted with hydrochloric acid as follows
NaHCO3(s) HCl(aq) ? NaCl(aq) CO2(g) H2O(l)
?H1
To give the same products we could carry out 2
other reactions
2NaHCO3(s) ? Na2CO3(s) CO2(g) H2O(l)
?H2
Na2CO3(s) 2HCl (aq) ? 2NaCl(aq) CO2(g)
H2O(l) ?H3

56
Hesss Law

The sodium hydrogencarbonate could be heated to
form sodium carbonate which is then reacted with
hydrochloric acid.
2NaHCO3(s) ? Na2CO3(s) CO2(g) H2O(l) ?H2
Na2CO3(s) 2HCl (aq) ? 2NaCl(aq) CO2(g)
H2O(l) ?H3

57
Hesss Law

If these two equations are added together the
Na2CO3 cancel out and the result is twice the
overall equation.
2NaHCO3(s) 2HCl(aq) --gt 2NaCl(aq) 2CO2(g)
2H2O(l)
Hesss Law says that the enthalpy change for the
two stage reaction must be equal to the single
stage process
2?H1 ?H2 ?H3
The number 2 is present in front of ?H1 as the
equations must all be balanced.

58
Hesss Law

This can also be shown using an enthalpy cycle

59
Hesss Law

To read an energy cycle you must identify the
reactants and products that you are being asked
about and make sure all 3 sides are balanced.
Then you must identify the alternative route you
will take to get from reactants to products.

60
Hesss Law

If you are following an arrow then you add all
those ?H values. You then subtract any ?H values
when you go in the opposite direction of the
arrow.

61
Hesss Law

You can also use a series of equations and
compare them to find the unknown enthalpy change.
For example
S(s) 1½O2(g) ? SO3(g) ?H-395 kJ ?H1
SO2(g) ½O2(g) ? SO3(g) ?H-98 kJ ?H2
Calculate the standard enthalpy change, ?H for
the reaction
S(s) O2 ? SO2(g)

62
Hesss Law

?H1 has the same reactants as the reaction in
question.
?H2 relates SO3(g) to SO2(g) but the SO2 is on
the opposite side of the equation from the
reaction in question. This means we reverse the
chemical change and the sign of ?H2.
The equations can now be combined and the values
added to find the ?H
?H -395 98 -297 kJ

63
Hesss Law Activity Worksheet