rates of reaction a guide for gcse students 2010 specifications knockhardy publishing
TRANSCRIPT
RATES OF RATES OF REACTIONREACTION
A guide for GCSE studentsA guide for GCSE students
2010 2010 SPECIFICATIONSSPECIFICATIONSKNOCKHARDY PUBLISHINGKNOCKHARDY PUBLISHING
RATES OF REACTIONRATES OF REACTION
INTRODUCTION
This Powerpoint show is one of several produced to help students understand selected GCSE Chemistry topics. It is based on the requirements of the AQA specification but is suitable for other examination boards.
Individual students may use the material at home for revision purposes and it can also prove useful for classroom teaching with an interactive white board.
Accompanying notes on this, and the full range of AS and A2 Chemistry topics, are available from the KNOCKHARDY WEBSITE at...
www.knockhardy.org.uk
All diagrams and animations in this Powerpoint are original and created by Jonathan Hopton. Permission must be obtained for their use in any commercial work.
All diagrams and animations in this Powerpoint are original and created by Jonathan Hopton. Permission must be obtained for their use in any commercial work.
THE IMPORTANCE OF REACTION RATETHE IMPORTANCE OF REACTION RATE
Being able to speed up or slow down chemicalreactions 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 temperatureto save energy or be safer
THE IMPORTANCE OF REACTION RATETHE IMPORTANCE OF REACTION RATE
Being able to speed up or slow down chemicalreactions 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 temperatureto save energy or be safer
Changes in temperature concentration of solutiongas pressure surface area of solids
plus the presence of catalysts
all affect the rate of reactions.
COLLISION THEORYCOLLISION THEORY
Explains why the rate of reaction changes
It states ‘particles must COLLIDE before a reaction can take place’
NO COLLISIONNo chance of a reaction
taking place
COLLISIONA reaction mightnow take place
COLLISION THEORYCOLLISION 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’
NO COLLISIONNo chance of a reaction
taking place
COLLISIONA reaction mightnow take place
BUT
COLLISION THEORYCOLLISION 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
COLLISION THEORYCOLLISION 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’
NOT ENOUGH ENERGYNo chance of a reaction
taking place
ENOUGH ENERGYA reaction willnow take place
COLLISION THEORYCOLLISION THEORY
Explains why the rate of reaction changes
According to collision theory, to increase the rate of reaction you therefore need...
COLLISION THEORYCOLLISION THEORY
Explains why the rate of reaction changes
According to collision theory, to increase the rate of reaction you therefore need...
more frequent collisions
COLLISION THEORYCOLLISION 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
COLLISION THEORYCOLLISION 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
COLLISION THEORYCOLLISION 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
INCREASING THE RATE OF REACTIONINCREASING 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)
• 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)
INCREASING SURFACE AREAINCREASING SURFACE AREA
INCREASING SURFACE AREAINCREASING SURFACE AREA
• Increasing surface area increases chances of a collision - more particles are exposed
INCREASING SURFACE AREAINCREASING SURFACE AREA
• Increasing surface area increases chances of a collision - more particles are exposed
• Powdered solids react quicker than larger lumps
INCREASING SURFACE AREAINCREASING 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
INCREASING SURFACE AREAINCREASING 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
3
3
SURFACE AREA9+9+3+3+3+3 = 30 sq units
1
INCREASING SURFACE AREAINCREASING 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
3
3
SURFACE AREA9+9+3+3+3+3 = 30 sq units
1
INCREASING SURFACE AREAINCREASING 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
3
3
SURFACE AREA9+9+3+3+3+3 = 30 sq units
1
INCREASING SURFACE AREAINCREASING 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
3
3
SURFACE AREA9+9+3+3+3+3 = 30 sq units
NEW SURFACE AREA9 x (1+1+1+1+1+1) = 54 sq units
1
111
INCREASING SURFACE AREAINCREASING 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
3
3
SURFACE AREA9+9+3+3+3+3 = 30 sq units
NEW SURFACE AREA9 x (1+1+1+1+1+1) = 54 sq units
1
111
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
INCREASING THE TEMPERATUREINCREASING 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 TEMPERATUREINCREASING THE TEMPERATURE
ENERGY CHANGES DURING A REACTION
During a reaction the enthalpy (a form of energy) rises to a maximum, then falls
• 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
START OF REATION
END OF REATION
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
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)
• 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
ACTIVATION ENERGY
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
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.
• 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
ACTIVATION ENERGY
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
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.
If they don’t have enough energy they will not get over the barrier.
• 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
ACTIVATION ENERGY
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
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.
If they have enough energy they will get over the barrier.
• 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
ACTIVATION ENERGY
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
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.
If more energy is given to the reactants then they are more likely to react.
• 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
ACTIVATION ENERGY
INCREASING THE TEMPERATUREINCREASING THE TEMPERATURE
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.
If more energy is given to the reactants then they are more likely to react.
• 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
ACTIVATION ENERGY
ADDING A CATALYSTADDING A CATALYST
• Catalysts provide an alternative reaction pathway with a lower Activation Energy (Ea)
ADDING A CATALYSTADDING 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
ADDING A CATALYSTADDING 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
ADDING A CATALYSTADDING A CATALYST
WITHOUT 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
ADDING A CATALYSTADDING A CATALYST
WITHOUT A CATALYST WITH A CATALYST
NEW PATHWAY
• 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
ADDING A CATALYSTADDING 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
ADDING A CATALYSTADDING 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
ADDING A CATALYSTADDING 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
ADDING A CATALYSTADDING A CATALYST
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 ECONOMYREDUCE WASTE
3 Are often enzymes GENERATE SPECIFIC PRODUCTSOPERATE EFFECTIVELY AT ROOM TEMPS
4 Have great economic importance POLY(ETHENE) in the industrial production of SULPHURIC ACID
AMMONIAETHANOL
5 Can reduce pollution CATALYTIC CONVERTERS
CATALYSTS – CATALYSTS – USEFUL POINTSUSEFUL POINTS
INCREASING THE CONCENTRATION OF SOLUTIONSINCREASING THE CONCENTRATION OF SOLUTIONS
INCREASING THE CONCENTRATION OF SOLUTIONSINCREASING THE CONCENTRATION OF SOLUTIONS
Increasing concentration = more frequent collisions = increased rate of reaction
Low concentrationfewer collisions
Higher concentrationmore collisions
= FASTER
INCREASING THE PRESSURE OF GASESINCREASING THE PRESSURE OF GASES
INCREASING THE PRESSURE OF GASESINCREASING THE PRESSURE OF GASES
• increasing the pressure forces gas particles closer together
INCREASING THE PRESSURE OF GASESINCREASING THE PRESSURE OF GASES
• increasing the pressure forces gas particles closer together
• this increases the frequency of collisions so the rate increases
INCREASING THE PRESSURE OF GASESINCREASING 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
INCREASING THE PRESSURE OF GASESINCREASING 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
INCREASING THE PRESSURE OF GASESINCREASING 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
INCREASING THE PRESSURE OF GASESINCREASING 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
INCREASING THE PRESSURE OF GASESINCREASING 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
more frequent collisions = greater chance of a reaction
THE EFFECT OF LIGHT ON CHEMICAL REACTIONSTHE EFFECT OF LIGHT ON CHEMICAL REACTIONS
THE EFFECT OF LIGHT ON CHEMICAL REACTIONSTHE 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
MEASURING REACTION RATESMEASURING REACTION RATES
MEASURING REACTION RATESMEASURING REACTION RATES
Reactions are fastest at the start and get slower as the concentration of the reactants drops.
MEASURING REACTION RATESMEASURING REACTION RATES
Reactions are fastest at the start and get slower as the concentration of the reactants drops.
Consider the reaction A + B C
MEASURING REACTION RATESMEASURING 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)
MEASURING REACTION RATESMEASURING 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
TIME
CO
NC
EN
TR
AT
ION
B A
C
MEASURING REACTION RATESMEASURING 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
TIME
CO
NC
EN
TR
AT
ION
B A
C
MEASURING REACTION RATESMEASURING 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
TIME
CO
NC
EN
TR
AT
ION
B A
C
MEASURING REACTION RATESMEASURING 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
TIME
CO
NC
EN
TR
AT
ION
B A
C
MEASURING REACTION RATESMEASURING 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
INTERPRETING GRAPHS INVOLVING RATESINTERPRETING GRAPHS INVOLVING RATES
Magnesium turnings are added to dilute dilute hydrochloric acid and
the volume of hydrogen gas produced is measured at set times
Magnesium turnings are added to dilute dilute hydrochloric acid and
the volume of hydrogen gas produced is measured at set times
INTERPRETING GRAPHS INVOLVING RATESINTERPRETING GRAPHS INVOLVING RATES
A
B
C
INTERPRETING GRAPHS INVOLVING RATESINTERPRETING GRAPHS INVOLVING RATES
AAt the start of the reaction the
concentrations are at a maximum so the graph will have the STEEPEST SLOPE
AAt the start of the reaction the
concentrations are at a maximum so the graph will have the STEEPEST SLOPE
A
B
C
INTERPRETING GRAPHS INVOLVING RATESINTERPRETING GRAPHS INVOLVING RATES
BAs the reactants are used up
the collisions go down and the rate drops steadily – CURVE
STEADILY GETS LESS STEEP
BAs the reactants are used up
the collisions go down and the rate drops steadily – CURVE
STEADILY GETS LESS STEEP
A
B
C
INTERPRETING GRAPHS INVOLVING RATESINTERPRETING GRAPHS INVOLVING RATES
CAt the end of the reaction, all
the reactants have been used – no more gas is produced and
the CURVE IS LEVEL
CAt the end of the reaction, all
the reactants have been used – no more gas is produced and
the CURVE IS LEVEL
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
QUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
X 2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium turnings + 50cm3 2M hydrochloric acid (excess) at 25°C
1g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
CONCENTRATION EFFECTSQUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
CONCENTRATION EFFECTS
X 2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium turnings + 50cm3 2M hydrochloric acid (excess) at 25°C
1g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
QUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
TEMPERATURE EFFECTS
X 2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 35°C
2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 55°C
QUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
TEMPERATURE EFFECTS
X 2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 35°C
2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 55°C
QUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
PARTICLE SIZE EFFECTS
X 2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium ribbon + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium powder + 50cm3 1M hydrochloric acid (excess) at 25°C
2.5g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
QUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
PARTICLE SIZE EFFECTS
X 2g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium ribbon + 50cm3 1M hydrochloric acid (excess) at 25°C
2g of magnesium powder + 50cm3 1M hydrochloric acid (excess) at 25°C
2.5g of magnesium turnings + 50cm3 1M hydrochloric acid (excess) at 25°C
QUESTIONS ABOUT RATE GRAPHSQUESTIONS ABOUT RATE GRAPHS
© 2011 © 2011 JONATHAN HOPTON & KNOCKHARDY PUBLISHINGJONATHAN HOPTON & KNOCKHARDY PUBLISHING
RATE OF RATE OF REACTIONREACTION
THE ENDTHE END