RATES OF REACTION

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RATES OF REACTION

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RATES OF REACTION Magnesium turnings are added to dilute dilute hydrochloric acid and the volume of hydrogen gas produced is measured at set times INTERPRETING GRAPHS ... – PowerPoint PPT presentation

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Title: RATES OF REACTION

1
RATES OF REACTION
2
RATES OF REACTION
3
THE IMPORTANCE OF REACTION RATE
Being able to speed up or slow down
chemical reactions is important in industry and
in everyday life. Reactions which take place
slowly may need to be speeded up which are too
fast may need to be controlled may need to be
carried out at a lower temperature to save
energy or be safer
4
THE IMPORTANCE OF REACTION RATE
Being able to speed up or slow down
chemical reactions is important in industry and
in everyday life. Reactions which take place
slowly may need to be speeded up which are too
fast may need to be controlled may need to be
carried out at a lower temperature to save
energy or be safer Changes in
temperature concentration of solution gas
pressure surface area of solids plus the
presence of catalysts all affect the rate of
reactions.
5
COLLISION THEORY
Explains why the rate of reaction changes It
states particles must COLLIDE before a
reaction can take place
NO COLLISION No chance of a reaction taking place
COLLISION A reaction might now take place
6
COLLISION THEORY
Explains why the rate of reaction changes It
states particles must COLLIDE before a
reaction can take place not all
collisions lead to a reaction
BUT
NO COLLISION No chance of a reaction taking place
COLLISION A reaction might now take place
7
COLLISION THEORY
Explains why the rate of reaction changes It
states particles must COLLIDE before a
reaction can take place not all
collisions lead to a reaction reactants
must have at least a minimum amount of energy
known as the ACTIVATION ENERGY in order to
react
BECAUSE
8
COLLISION THEORY
Explains why the rate of reaction changes It
states particles must COLLIDE before a
reaction can take place not all
collisions lead to a reaction reactants
must have at least a minimum amount of energy
known as the ACTIVATION ENERGY in order to
react
9
COLLISION THEORY
Explains why the rate of reaction
changes According to collision theory, to
increase the rate of reaction you therefore
need...
10
COLLISION THEORY
Explains why the rate of reaction
changes According to collision theory, to
increase the rate of reaction you therefore
need... more frequent collisions
11
COLLISION THEORY
Explains why the rate of reaction
changes According to collision theory, to
increase the rate of reaction you therefore
need... more frequent collisions increase
particle speed or have more
particles present
12
COLLISION THEORY
Explains why the rate of reaction
changes According to collision theory, to
increase the rate of reaction you therefore
need... more frequent collisions increase
particle speed or have more
particles present more successful collisions

13
COLLISION THEORY
Explains why the rate of reaction
changes According to collision theory, to
increase the rate of reaction you therefore
need... more frequent collisions increase
particle speed or have more
particles present more successful collisions
give particles more energy or
lower the activation energy
14
INCREASING THE RATE OF REACTION
The following methods can be used

INCREASE THE SURFACE AREA OF SOLIDS
INCREASE TEMPERATURE
ADD A CATALYST
INCREASE THE CONCENTRATION OF REACTANTS
INCREASE THE PRESSURE OF ANY GASES
SHINE LIGHT (a limited number of reactions)

15
INCREASING SURFACE AREA
16
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed

17
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps

18
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps
Catalysts (e.g. in catalytic converters) are in
a finely
divided form for this reason

19
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps
Catalysts (e.g. in catalytic converters) are in
a finely
divided form for this reason

1
3
3
SURFACE AREA 993333 30 sq units
20
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps
Catalysts (e.g. in catalytic converters) are in
a finely
divided form for this reason

1
3
3
SURFACE AREA 993333 30 sq units
21
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps
Catalysts (e.g. in catalytic converters) are in
a finely
divided form for this reason

CUT THE SHAPE INTO SMALLER PIECES
1
3
3
SURFACE AREA 993333 30 sq units
22
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps
Catalysts (e.g. in catalytic converters) are in
a finely
divided form for this reason

1
CUT THE SHAPE INTO SMALLER PIECES
1
1
1
3
3
SURFACE AREA 993333 30 sq units
NEW SURFACE AREA 9 x (111111) 54 sq units
23
INCREASING SURFACE AREA

Increasing surface area increases chances of a
collision
- more particles are exposed
Powdered solids react quicker than larger lumps
Catalysts (e.g. in catalytic converters) are in
a finely
divided form for this reason

1
CUT THE SHAPE INTO SMALLER PIECES
1
1
1
3
3
SURFACE AREA 993333 30 sq units
NEW SURFACE AREA 9 x (111111) 54 sq units
24
INCREASING THE TEMPERATURE
25
INCREASING THE TEMPERATURE

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

26
INCREASING THE TEMPERATURE

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

ENERGY CHANGES DURING A REACTION During a
reaction the enthalpy (a form of energy) rises to
a maximum, then falls
START OF REATION
END OF REATION
27
INCREASING THE TEMPERATURE

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

ENERGY CHANGES DURING A REACTION During a
reaction the enthalpy (a form of energy) rises to
a maximum, then falls A minimum of energy is
needed to overcome the ACTIVATION ENERGY
(Ea) Only reactants with energy equal to, or
greater than, this value will react.
ACTIVATION ENERGY
29
INCREASING THE TEMPERATURE

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

increasing the temperature increases the rate of
a reaction
particles get more energy - more overcome the
energy barrier
particle speeds also increase - collisions are
more frequent

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)

35
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react

36
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react

WITHOUT A CATALYST
37
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react

NEW PATHWAY
WITHOUT A CATALYST
WITH A CATALYST
38
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react
Catalysts remain chemically unchanged at the
end of the reaction
- they are not used up

39
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react
Catalysts remain chemically unchanged at the
end of the reaction
- they are not used up
Using catalysts avoids the need for extra heat
- safer and cheaper

40
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react
Catalysts remain chemically unchanged at the
end of the reaction
- they are not used up
Using catalysts avoids the need for extra heat
- safer and cheaper
They are used in industry especially where an
increase in
temperature results in a lower yield due to a
shift in equilibrium

41
ADDING A CATALYST

Catalysts provide an alternative reaction
pathway with a lower
Activation Energy (Ea)
Decreasing the Activation Energy means that
more particles will
have sufficient energy to overcome the energy
barrier and react
Catalysts remain chemically unchanged at the
end of the reaction
- they are not used up
Using catalysts avoids the need for extra heat
- safer and cheaper
They are used in industry especially where an
increase in
temperature results in a lower yield due to a
shift in equilibrium
Examples include the Haber and Contact Processes

42
CATALYSTS USEFUL POINTS
Catalysts are widely used in industry because
they 1 Allow reactions to take place SAVE
ENERGY (lower Ea) at lower temperatures
REDUCE CO2 OUTPUT 2 Enable different
reactions to be used BETTER ATOM
ECONOMY REDUCE WASTE 3 Are often
enzymes GENERATE SPECIFIC PRODUCTS OPERATE
EFFECTIVELY AT ROOM TEMPS 4 Have great economic
importance POLY(ETHENE) in the industrial
production of SULPHURIC ACID AMMONIA ET
HANOL 5 Can reduce pollution CATALYTIC
CONVERTERS
43
INCREASING THE CONCENTRATION OF SOLUTIONS
44
INCREASING THE CONCENTRATION OF SOLUTIONS
Increasing concentration more
frequent collisions increased rate of
reaction
Low concentration fewer collisions
Higher concentration more collisions FASTER
45
INCREASING THE PRESSURE OF GASES
46
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together

47
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together
this increases the frequency of collisions so
the rate increases

48
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together
this increases the frequency of collisions so
the rate increases
many industrial processes occur at high
pressure to increase
the rate... but it can adversely affect the
yield

49
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together
this increases the frequency of collisions so
the rate increases
many industrial processes occur at high
pressure to increase
the rate... but it can adversely affect the
yield

50
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together
this increases the frequency of collisions so
the rate increases
many industrial processes occur at high
pressure to increase
the rate... but it can adversely affect the
yield
more particles in a given volume greater
pressure

51
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together
this increases the frequency of collisions so
the rate increases
many industrial processes occur at high
pressure to increase
the rate... but it can adversely affect the
yield
more particles in a given volume greater
pressure
greater pressure more frequent collisions

52
INCREASING THE PRESSURE OF GASES

increasing the pressure forces gas particles
closer together
this increases the frequency of collisions so
the rate increases
many industrial processes occur at high
pressure to increase
the rate... but it can adversely affect the
yield
more particles in a given volume greater the
pressure
greater pressure more frequent collisions

53
THE EFFECT OF LIGHT ON CHEMICAL REACTIONS
54
THE EFFECT OF LIGHT ON CHEMICAL REACTIONS
Shining a suitable light source can speed up some
reactions The light provides energy to break
bonds and start a reaction The greater the
intensity of the light, the greater the
effect Examples PHOTOSYNTHESIS
DARKENING OF SILVER SALTS IN B/W PHOTOGRAPHY
55
MEASURING REACTION RATES
56
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.
57
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.
Consider the reaction A B
C
58
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.
Consider the reaction A B
C Reactants (A and B) Product (C)
59
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.
Consider the reaction A B
C Reactants (A and B) Product
(C) Concentration decreases Concentration
increases
60
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.

Consider the reaction A B
C
Reactants (A and B) Product (C)
Concentration decreases Concentration
increases
steeper curve faster reaction

61
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.

Consider the reaction A B
C
Reactants (A and B) Product (C)
Concentration decreases Concentration
increases
steeper curve faster reaction
reactions start off quickly
because of the greater chance
of a collision

62
MEASURING REACTION RATES
Reactions are fastest at the start and get slower
as the concentration of the reactants drops.

Consider the reaction A B
C
Reactants (A and B) Product (C)
Concentration decreases Concentration
increases
steeper curve faster reaction
reactions start off quickly
because of the greater chance
of a collision
reactions slow down as there
are fewer reactants to collide

63
MEASURING REACTION RATES
The rate of a chemical reaction can be found by
measuring the amount of a reactant used or the
amount of product formed over time. eg rate of
reaction amount of reactant used time
or amount of product formed
time
64
MEASURING REACTION RATES
RATE How much concentration changes with time.
THE SLOPE OF THE GRADIENT OF THE CURVE GETS LESS
AS THE REACTION SLOWS DOWN WITH TIME
CONCENTRATION
y
x
TIME

the rate is found from the slope (gradient) of
the curve
the slope at the start of the reaction will
give the INITIAL RATE
the slope gets less as the reaction proceeds

65
INTERPRETING GRAPHS INVOLVING RATES
66
INTERPRETING GRAPHS INVOLVING RATES
Magnesium turnings are added to dilute dilute
hydrochloric acid and the volume of hydrogen gas
produced is measured at set times
67
INTERPRETING GRAPHS INVOLVING RATES
C
B
A At the start of the reaction the concentrations
are at a maximum so the graph will have the
STEEPEST SLOPE
A
68
INTERPRETING GRAPHS INVOLVING RATES
C
B
B As the reactants are used up the collisions go
down and the rate drops steadily CURVE STEADILY
GETS LESS STEEP
A
69
INTERPRETING GRAPHS INVOLVING RATES
C
B
C At the end of the reaction, all the reactants
have been used no more gas is produced and the
CURVE IS LEVEL
A
70
QUESTIONS ABOUT RATE GRAPHS
Reaction between magnesium and hydrochloric acid
IN THE FOLLOWING GRAPHS YOU WILL BE TOLD THE
CONDITIONS THAT PRODUCE GRAPH X AND BE GIVEN A
SET OF OTHER CONDITIONS. YOU WILL HAVE TO MATCH
THE CONDITIONS TO THE GRAPHS A, B and C
71
QUESTIONS ABOUT RATE GRAPHS
CONCENTRATION EFFECTS
X 2g of magnesium turnings 50cm3 1M
hydrochloric acid (excess) at 25C 2g of
magnesium turnings 50cm3 2M hydrochloric acid
(excess) at 25C 1g of magnesium turnings
50cm3 1M hydrochloric acid (excess) at 25C
72
QUESTIONS ABOUT RATE GRAPHS
CONCENTRATION EFFECTS
X 2g of magnesium turnings 50cm3 1M
hydrochloric acid (excess) at 25C 2g of
magnesium turnings 50cm3 2M hydrochloric acid
(excess) at 25C 1g of magnesium turnings
50cm3 1M hydrochloric acid (excess) at 25C
73
QUESTIONS ABOUT RATE GRAPHS
TEMPERATURE EFFECTS
X 2g of magnesium turnings 50cm3 1M
hydrochloric acid (excess) at 35C 2g of
magnesium turnings 50cm3 1M hydrochloric acid
(excess) at 25C 2g of magnesium turnings
50cm3 1M hydrochloric acid (excess) at 55C
74
QUESTIONS ABOUT RATE GRAPHS
TEMPERATURE EFFECTS
X 2g of magnesium turnings 50cm3 1M
hydrochloric acid (excess) at 35C 2g of
magnesium turnings 50cm3 1M hydrochloric acid
(excess) at 25C 2g of magnesium turnings
50cm3 1M hydrochloric acid (excess) at 55C
75
QUESTIONS ABOUT RATE GRAPHS
PARTICLE SIZE EFFECTS
X 2g of magnesium turnings 50cm3 1M
hydrochloric acid (excess) at 25C 2g of
magnesium ribbon 50cm3 1M hydrochloric acid
(excess) at 25C 2g of magnesium powder 50cm3
1M hydrochloric acid (excess) at 25C 2.5g of
magnesium turnings 50cm3 1M hydrochloric acid
(excess) at 25C
76
QUESTIONS ABOUT RATE GRAPHS
PARTICLE SIZE EFFECTS
X 2g of magnesium turnings 50cm3 1M
hydrochloric acid (excess) at 25C 2g of
magnesium ribbon 50cm3 1M hydrochloric acid
(excess) at 25C 2g of magnesium powder 50cm3
1M hydrochloric acid (excess) at 25C 2.5g of
magnesium turnings 50cm3 1M hydrochloric acid
(excess) at 25C
77
RATE OF REACTION THE END

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