iGCSE Chemistry Section 4 Lesson 3 new syllabus.ppt

IGCSE CHEMISTRY
SECTION 4 LESSON 3

Content
The iGCSE
Chemistry
course
Section 1 Principles of Chemistry
Section 2 Chemistry of the Elements
Section 3 Organic Chemistry
Section 4 Physical Chemistry
Section 5 Chemistry in Society

Content
Section 4
Physical
Chemistry
a) Acids, alkalis and salts
b) Energetics
c) Rates of reaction
d) Equilibria

Lesson 3
c) Rates of
reaction
c) Rates of reaction
4.17 describe experiments to investigate the effects of
changes in surface area of a solid, concentration of
solutions, temperature and the use of a catalyst on the
rate of a reaction
4.18 describe the effects of changes in surface area of a
solid, concentration of solutions, pressure of gases,
temperature and the use of a catalyst on the rate of a
reaction
4.19 understand the term activation energy and represent
it on a reaction profile
4.20 explain the effects of changes in surface area of a
solid, concentration of solutions, pressure of gases and
temperature on the rate of a reaction in terms of particle
collision theory
4.21 explain that a catalyst speeds up a reaction by
providing an alternative pathway with lower activation
energy.

Rates of Reaction
The rate of reaction
is the rate at which
products are formed,
or the rate at which
reactions are used up,
in a reaction.

Rates of Reaction
Chemical
reactions will only
occur when the
reacting particles
collide with each
other with
sufficient energy
so they react.

Rates of Reaction
Chemical
reactions will only
occur when the
reacting particles
collide with each
other with
sufficient energy
so they react.
The
ACTIVATION
ENERGY is the
minimum amount
of energy
required to cause
the reaction to
happen.

Rates of Reaction
Chemical
reactions will only
occur when the
reacting particles
collide with each
other with
sufficient energy
so they react.
The
ACTIVATION
ENERGY is the
minimum amount
of energy
required to cause
the reaction to
happen.
There are FIVE very important factors
which can affect the rate of reaction.

Rates of Reaction
Temperature
Pressure
(of gases)

Rates of Reaction
Temperature
Pressure
(of gases)
Concentration

Rates of Reaction
Temperature
Pressure
(of gases)
Concentration
Surface Area

Rates of Reaction
Temperature
Pressure
(of gases)
Concentration
Surface Area
Catalysts

Rates of Reaction
Temperature
Pressure
(of gases)
Concentration
Surface Area
Catalysts
Let’s not forget
here a little
dose of kinetic
theory

Rates of Reaction
Temperature
Pressure
(of gases)
Concentration
Surface Area
Catalysts
Let’s not forget
here a little
dose of kinetic
theory
Kinetic
what?

Rates of Reaction
Kinetic theory
is all about the
random
movement of
particles

Rates of Reaction
Kinetic theory
is all about the
random
movement of
particles
Kinetic theory assumes
that particles are in
constant random motion

Rates of Reaction
Kinetic theory
is all about the
random
movement of
particles
!
And there will be collisions!

Rates of Reaction
Kinetic theory
is all about the
random
movement of
particles
!
And there will be collisions!
It’s these collisions that are the
cause of chemical reactions.

Rates of Reaction
Do you remember
the five factors
that can affect
the rate of
chemical
reactions?

Rates of Reaction
Let’s now
consider each
one of these
factors in turn

Rates of Reaction
1. Temperature of the Reactants

Rates of Reaction
Cold conditions,
particles have little
energy, move slowly
and collide
infrequently and
less successfully
Low
temperature

Rates of Reaction
Cold conditions,
particles have little
energy, move slowly
and collide
infrequently and
less successfully
HEAT
When heated,
particles have more
energy, move faster,
collide frequently
and more
successfully
Low
temperature
High
temperature

Rates of Reaction
2. Concentration of the Dissolved
Reactants

Rates of Reaction
Reactants
Low
concentration
Particles are spread
out and will collide
with each other less
often, with fewer
successful collisions

Rates of Reaction
Reactants
Low
concentration
often, with fewer
Particles are
crowded close
together, so collide
more often, with
more successful
collisions
High
concentration

Rates of Reaction
3. Pressure (in gases)

Rates of Reaction
Low
pressure
often, with fewer

Rates of Reaction
Low
pressure
often, with fewer
High
pressure
Particles are pushed
closer together,
they collide more
frequently, with
more successful
collisions

Rates of Reaction
4. Surface area of solid
reactants

Rates of Reaction
reactants
Small
surface
area
Large particles have a
small surface area in
relation to volume –
less particles exposed,
fewer collisions, slow
reaction

Rates of Reaction
reactants
Small
surface
area
Large particles have a
small surface area in
relation to volume –
less particles exposed,
fewer collisions, slow
reaction
Large
surface
area
Smaller particles have
a larger surface area in
relation to volume-
more particles
exposed, more
collisions, faster
reaction

Rates of Reaction
5. Using a catalyst

Rates of Reaction
5. Using a catalyst
A catalyst is a substance which increases the
rate of a chemical reaction without being used up
itself. It can be used over and over again.

Activation energy
What’s all this ‘ere talk
about the ACTIVATION
ENERGY?

Activation energy
What’s all this ‘ere talk
about the ACTIVATION
ENERGY?
The ACTIVATION
ENERGY is the relatively
small amount of energy
needed to start a
chemical reaction

Increasing
energy
reactants
products
Time
Activation energy
Activation energy
Used to break
apart the old
bonds

Increasing
energy
reactants
products
Time
Activation energy
Activation energy
using a catalyst.
Catalysts reduce the
activation energy for
the reaction – this
makes the reaction
go faster.

Rate of reaction experiments
1. Surface
area
Boiling tube
Bubbles of hydrogen
Magnesium ribbon
Hydrochloric acid
Time taken
for
magnesium
to disappear
= 109 secs

1. Surface
area
Boiling tube
Bubbles of hydrogen
Magnesium ribbon
Hydrochloric acid
Time taken
for
magnesium
to disappear
= 109 secs
Time taken
for
magnesium
to disappear
= 55 secs
Small
pieces of
Magnesium
ribbon

1. Surface
area
Boiling tube
Bubbles of hydrogen
Magnesium ribbon
Hydrochloric acid
Time taken
for
magnesium
to disappear
= 109 secs
Time taken
for
magnesium
to disappear
= 55 secs
Small
pieces of
Magnesium
ribbon
Increasing the surface area of
reactants increases the rate of
reaction

2.
Concentration
X
10cm3 sodium
thiosulphate +
40cm3 water +
10cm3
hydrochloric acid
View from
above
Volume of sodium
thiosulphate (cm3)
Volume of
water (cm3)
10 40
20 30
30 20
40 10
50 0

2.
Concentration
10cm3 sodium
thiosulphate +
40cm3 water +
10cm3
hydrochloric acid
View from
above
Volume of sodium
thiosulphate (cm3)
Volume of
water (cm3)
Time for cross
to disappear
(secs)
10 40 98
20 30 64
30 20 31
40 10 16
50 0 8

2.
Concentration
10cm3 sodium
thiosulphate +
40cm3 water +
10cm3
hydrochloric acid
View from
above
Volume of sodium
thiosulphate (cm3)
Volume of
water (cm3)
Time for cross
to disappear
(secs)
10 40 98
20 30 64
30 20 31
40 10 16
50 0 8
Volume of thiosulphate
Time
for
cross
to
disappear

2.
Concentration
10cm3 sodium
thiosulphate +
40cm3 water +
10cm3
hydrochloric acid
View from
above
Volume of sodium
thiosulphate (cm3)
Volume of
water (cm3)
Time for cross
to disappear
(secs)
10 40 98
20 30 64
30 20 31
40 10 16
50 0 8
Volume of thiosulphate
Time
for
cross
to
disappear
As the concentration of sodium
thiosulphate increases, so the
time taken decreases – the rate
of reaction gets faster.

3.
Temperature
Temperature
of reaction
mixture (oC)
Reaction time (secs) Average
reaction time
(secs)
Experiment 1 Experiment 2 Experiment 3
40 24 25 25 25
50 22 20 20 21
60 17 16 16 16
70 12 11 11 11
80 7 7 8 7

3.
Temperature
Temperature
of reaction
mixture (oC)
Reaction time (secs) Average
reaction time
(secs)
Experiment 1 Experiment 2 Experiment 3
40 24 25 25 25
50 22 20 20 21
60 17 16 16 16
70 12 11 11 11
80 7 7 8 7
As the temperature
increases so the time
taken for the cross
to disappear
decreases – the
reaction gets faster.

4.
Catalysts
Hydrogen
peroxide
Manganese oxide
catalyst
2H2O2  2H2O + O2
Decomposition of hydrogen peroxide
The rate of reaction is
measured by how long it
takes for the gas to be
produced.

4.
Catalysts
Hydrogen
peroxide
Manganese oxide
catalyst
2H2O2  2H2O + O2
Volume
of
gas
produced
(cm
3
)
100
80
60
40
20
0
0 10 20 30 40 50 60 70 80 90 100
Time (secs)
1
2
3

4.
Catalysts
Hydrogen
peroxide
Manganese oxide
catalyst
2H2O2  2H2O + O2
Volume
of
gas
produced
(cm
3
)
100
80
60
40
20
0
0 10 20 30 40 50 60 70 80 90 100
Time (secs)
1
2
3
Better catalysts give a quicker reaction
as shown by the steeper graph

4.
Catalysts
Hydrogen
peroxide
Manganese oxide
catalyst
2H2O2  2H2O + O2
The catalyst manganese oxide increases the
rate of decomposition of hydrogen peroxide.
Volume
of
gas
produced
(cm
3
)
100
80
60
40
20
0
0 10 20 30 40 50 60 70 80 90 100
Time (secs)
1
2
3
Better catalysts give a quicker reaction
as shown by the steeper graph

End of Section 4 Lesson 3
In this lesson we have covered:
Rates of Reaction
Activation Energy
Rates of Reaction Experiments

iGCSE Chemistry Section 4 Lesson 3 new syllabus.ppt

iGCSE Chemistry Section 4 Lesson 3 new syllabus.ppt

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