catalysis a guide for a level students knockhardy publishing 2015 specifications
DESCRIPTION
CONTENTS CONTENTS Enthalpy changes Activation Energy Heterogeneous catalysis Specificity Catalytic converters Homogeneous catalysis Autocatalysis Enzymes CATALYSISTRANSCRIPT
CATALYSISCATALYSISA guide for A level studentsA guide for A level students
KNOCKHARDY PUBLISHINGKNOCKHARDY PUBLISHING20152015
SPECIFICATIONSSPECIFICATIONS
CATALYSISCATALYSISINTRODUCTION
This Powerpoint show is one of several produced to help students understand selected topics at AS and A2 level Chemistry. It is based on the requirements of the AQA and OCR specifications but is suitable for other examination boards.
Individual students may use the material at home for revision purposes or it may be used for classroom teaching if an interactive white board is available.
Accompanying notes on this, and the full range of AS and A2 topics, are available from the KNOCKHARDY SCIENCE WEBSITE at...
www.knockhardy.org.uk/sci.htm
Navigation is achieved by...
either clicking on the grey arrows at the foot of each page
or using the left and right arrow keys on the keyboard
KNOCKHARDY PUBLISHINGKNOCKHARDY PUBLISHING
CONTENTSCONTENTS• Enthalpy changes
• Activation Energy
• Heterogeneous catalysis
• Specificity
• Catalytic converters
• Homogeneous catalysis
• Autocatalysis
• Enzymes
CATALYSISCATALYSIS
Before you start it would be helpful to…
• know how the basics of collision theory
• understand the importance of activation energy
• understand the importance of increasing the rate of reaction
CATALYSISCATALYSIS
CATALYSTS - backgroundCATALYSTS - backgroundAll reactions are accompanied by changes in enthalpy.
The enthalpy rises as the reaction starts because energy is being put in to break bonds.
It reaches a maximum then starts to fall as bonds are formed and energy is released.
ENTHALPY CHANGE DURINGAN EXOTHERMIC REACTION
CATALYSTS - backgroundCATALYSTS - backgroundAll reactions are accompanied by changes in enthalpy.
The enthalpy rises as the reaction starts because energy is being put in to break bonds.
It reaches a maximum then starts to fall as bonds are formed and energy is released.
ENTHALPY CHANGE DURINGAN EXOTHERMIC REACTION
If the…
FINAL ENTHALPY < INITIAL ENTHALPY
it is an EXOTHERMIC REACTION
and ENERGY IS GIVEN OUT
CATALYSTS - backgroundCATALYSTS - backgroundAll reactions are accompanied by changes in enthalpy.
The enthalpy rises as the reaction starts because energy is being put in to break bonds.
It reaches a maximum then starts to fall as bonds are formed and energy is released.
ENTHALPY CHANGE DURINGAN EXOTHERMIC REACTION
If the…
FINAL ENTHALPY < INITIAL ENTHALPY
it is an EXOTHERMIC REACTION
and ENERGY IS GIVEN OUT
FINAL ENTHALPY > INITIAL ENTHALPY
it is an ENDOTHERMIC REACTION
and ENERGY IS TAKEN IN
CATALYSTS - backgroundCATALYSTS - backgroundACTIVATION ENERGY - Ea
• Reactants will only be able to proceed to products if they have enough energy
• The energy is required to overcome an energy barrier
• Only those reactants with enough energy will get over
• The minimum energy required is known as the ACTIVATION ENERGY
ACTIVATION ENERGY Ea FORAN EXOTHERMIC REACTION
CATALYSTS - backgroundCATALYSTS - background
COLLISION THEORYCOLLISION THEORY
According to COLLISON THEORY a reaction will only take place if…
• PARTICLES COLLIDE
• PARTICLES HAVE AT LEAST A MINIMUM AMOUNT OF ENERGY
• PARTICLES ARE LINED UP CORRECTLY
CATALYSTS - backgroundCATALYSTS - background
COLLISION THEORYCOLLISION THEORY
According to COLLISON THEORY a reaction will only take place if…
• PARTICLES COLLIDE
• PARTICLES HAVE AT LEAST A MINIMUM AMOUNT OF ENERGY
• PARTICLES ARE LINED UP CORRECTLY
To increase the chances of a successful reaction you need to...
• HAVE MORE FREQUENT COLLISONS
• GIVE PARTICLES MORE ENERGY or
• DECREASE THE MINIMUM ENERGY REQUIRED
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MOLECULAR ENERGY Ea
DUE TO THE MANY COLLISONS TAKING PLACE IN GASES, THERE
IS A SPREAD OF MOLECULAR ENERGY AND VELOCITY
NUMBER OF MOLECULES WITH SUFFICIENT ENERGY TO OVERCOME THE ENERGY BARRIER
MAXWELL-BOLTZMANN DISTRIBUTION MAXWELL-BOLTZMANN DISTRIBUTION
The area under the curve beyond Ea corresponds to the number of molecules with sufficient energy to overcome the energy barrier and react.
If a catalyst is added, the Activation Energy is lowered - Ea will move to the left.
The area under the curve beyond Ea corresponds to the number of molecules with sufficient energy to overcome the energy barrier and react.
Lowering the Activation Energy, Ea, results in a greater area under the curve after Ea
showing that more molecules have energies in excess of the Activation Energy
Ea
EXTRA NUMBER OF MOLECULES WITH SUFFICIENT ENERGY TO OVERCOME THE ENERGY BARRIER
MAXWELL-BOLTZMANN DISTRIBUTION MAXWELL-BOLTZMANN DISTRIBUTION
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MOLECULAR ENERGY
DUE TO THE MANY COLLISONS TAKING PLACE IN GASES, THERE
IS A SPREAD OF MOLECULAR ENERGY AND VELOCITY
Catalysts work by providing…
“AN ALTERNATIVE REACTION PATHWAY WHICH HAS A LOWER ACTIVATION ENERGY”
CATALYSTS - lower ECATALYSTS - lower Eaa
A GREATER PROPORTION OF PARTICLES WILL HAVE ENERGIESIN EXCESS OF THE MINIMUM REQUIRED SO MORE WILL REACT
WITHOUT A CATALYST WITH A CATALYST
PRINCIPLES OF CATALYTIC ACTIONPRINCIPLES OF CATALYTIC ACTION
The two basic types of catalytic action are …
HETEROGENEOUS CATALYSISand
HOMOGENEOUS CATALYSIS
Format Catalysts are in a different phase to the reactantse.g. a solid catalyst in a gaseous reaction
Action takes place at active sites on the surface of a solidgases are adsorbed onto the surfacethey form weak bonds with metal atoms
Heterogeneous CatalysisHeterogeneous Catalysis
Format Catalysts are in a different phase to the reactantse.g. a solid catalyst in a gaseous reaction
Action takes place at active sites on the surface of a solidgases are adsorbed onto the surfacethey form weak bonds with metal atoms
Catalysis is thought to work in three stages...
AdsorptionAdsorption
ReactionReaction
DesorptionDesorption
Heterogeneous CatalysisHeterogeneous Catalysis
Heterogeneous CatalysisHeterogeneous Catalysis
For an explanation of what happens click on the numbers in turn, starting with
Heterogeneous CatalysisHeterogeneous Catalysis
Adsorption (STEP 1)Incoming species lands on an active site and forms bonds with the catalyst. It may use some of the bonding electrons in the molecules thus weakening them and making a subsequent reaction easier.
Heterogeneous CatalysisHeterogeneous Catalysis
Adsorption (STEP 1)Incoming species lands on an active site and forms bonds with the catalyst. It may use some of the bonding electrons in the molecules thus weakening them and making a subsequent reaction easier.
Reaction (STEPS 2 and 3)Adsorbed gases may be held on the surface in just the right orientation for a reaction to occur.This increases the chances of favourable collisions taking place.
Heterogeneous CatalysisHeterogeneous Catalysis
Desorption (STEP 4)There is a re-arrangement of electrons and the products are then released from the active sites
Adsorption (STEP 1)Incoming species lands on an active site and forms bonds with the catalyst. It may use some of the bonding electrons in the molecules thus weakening them and making a subsequent reaction easier.
Reaction (STEPS 2 and 3)Adsorbed gases may be held on the surface in just the right orientation for a reaction to occur.This increases the chances of favourable collisions taking place.
ANIMATION
Heterogeneous CatalysisHeterogeneous Catalysis
Desorption (STEP 4)There is a re-arrangement of electrons and the products are then released from the active sites
Adsorption (STEP 1)Incoming species lands on an active site and forms bonds with the catalyst. It may use some of the bonding electrons in the molecules thus weakening them and making a subsequent reaction easier.
Reaction (STEPS 2 and 3)Adsorbed gases may be held on the surface in just the right orientation for a reaction to occur.This increases the chances of favourable collisions taking place.
Heterogeneous CatalysisHeterogeneous CatalysisANIMATIONANIMATION
STRENGTH OF ADSORPTIONSTRENGTH OF ADSORPTION
The STRENGTH OF ADSORPTION is critical ...
too weak Ag little adsorption - few available d orbitalstoo strong W molecules remain on the surface preventing further reactionjust right Ni/Pt molecules are held but not too strongly so they can get away
Catalysis of gaseous reactions can lead to an increase in rate in several ways
• one species is adsorbed onto the surface and is more likely to undergo a collision• one species is held in a favourable position for reaction to occur• adsorption onto the surface allows bonds to break and fragments react quicker• two reactants are adsorbed alongside each other give a greater concentration
EXAMPLES OF CATALYSTSEXAMPLES OF CATALYSTS
Metals Ni, Pt hydrogenation reactions Fe Haber Process Rh, Pd catalytic converters
Oxides Al2O3 dehydration reactions V2O5 Contact Process
Format FINELY DIVIDED increases the surface areaprovides more collision sites
IN A SUPPORT MEDIUM maximises surface area and reduces costs
SpecificitySpecificityIn some cases the choice of catalyst can influence the products
Ethanol undergoes different reactions depending on the metal used as the catalyst.The distance between active sites and their similarity with the length of bondsdetermines the method of adsorption and affects which bonds are weakened.
CLICK HERE FOR ANIMATION
SpecificitySpecificityIn some cases the choice of catalyst can influence the products
Ethanol undergoes different reactions depending on the metal used as the catalyst.The distance between active sites and their similarity with the length of bondsdetermines the method of adsorption and affects which bonds are weakened.
SpecificitySpecificityIn some cases the choice of catalyst can influence the products
C2H5OH ——> CH3CHO + H2 C2H5OH ——> C2H4 + H2O
Ethanol undergoes different reactions depending on the metal used as the catalyst.The distance between active sites and their similarity with the length of bondsdetermines the method of adsorption and affects which bonds are weakened.
Alumina DehydrationCopper Dehydrogenation (oxidation)
Ethanol undergoes two different reactions depending on the metal used as the catalyst.
COPPER Dehydrogenation (oxidation)
C2H5OH ——> CH3CHO + H2
The active sites are the same distanceapart as the length of an O-H bond
It breaks to release hydrogen
ALUMINA Dehydration (removal of water)
C2H5OH ——> C2H4 + H2O
The active sites are the same distanceapart as the length of a C-O bond
It breaks to release an OH group
SpecificitySpecificity
PoisoningPoisoningImpurities in a reaction mixture can also adsorb onto the surface of a catalyst thus removing potential sites for gas molecules and decreasing efficiency.
expensive because... the catalyst has to replaced the process has to be shut down
examples Sulphur Haber processLead catalytic converters in cars
Catalytic convertersCatalytic convertersPURPOSE removing the pollutant gases formed in
internal combustion engines
POLLUTANTS CARBON MONOXIDENITROGEN OXIDESUNBURNT HYDROCARBONS
Catalytic convertersCatalytic convertersPURPOSE removing the pollutant gases formed
in internal combustion engines
POLLUTANTS CARBON MONOXIDENITROGEN OXIDESUNBURNT HYDROCARBONS
CONSTRUCTION made from alloys of platinum, rhodium and palladiumcatalyst is mounted in a support medium to spread it out honeycomb construction to ensure maximum gas contact
finely divided to increase surface area / get more collisionsinvolves HETEROGENEOUS CATALYSIS
Pollutant gasesPollutant gasesCarbon monoxide CO
Origin incomplete combustion of hydrocarbons in petrol when not enoughoxygen is present to convert all the carbon to carbon dioxide
C8H18(g) + 8½O2(g) ——> 8CO(g) + 9H2O(l)
Pollutant gasesPollutant gasesCarbon monoxide CO
Origin incomplete combustion of hydrocarbons in petrol when not enoughoxygen is present to convert all the carbon to carbon dioxide
C8H18(g) + 8½O2(g) ——> 8CO(g) + 9H2O(l)
Effect poisonouscombines with haemoglobin in bloodprevents oxygen being carried to cells
Pollutant gasesPollutant gasesCarbon monoxide CO
Origin incomplete combustion of hydrocarbons in petrol when not enoughoxygen is present to convert all the carbon to carbon dioxide
C8H18(g) + 8½O2(g) ——> 8CO(g) + 9H2O(l)
Effect poisonouscombines with haemoglobin in bloodprevents oxygen being carried to cells
Removal 2CO(g) + O2(g) ——> 2CO2(g)
2CO(g) + 2NO(g) ——> N2(g) + 2CO2(g)
Pollutant gasesPollutant gasesOxides of nitrogen NOx - NO, N2O and NO2
Origin nitrogen and oxygen combine under high temperature conditionsnitrogen combines with oxygen N2(g) + O2(g) ——> 2NO(g)nitrogen monoxide is oxidised 2NO(g) + O2(g) ——> 2NO2(g)
Pollutant gasesPollutant gasesOxides of nitrogen NOx - NO, N2O and NO2
Origin nitrogen and oxygen combine under high temperature conditionsnitrogen combines with oxygen N2(g) + O2(g) ——> 2NO(g)nitrogen monoxide is oxidised 2NO(g) + O2(g) ——> 2NO2(g)
Effect photochemical smog - irritating to eyes, nose and throatproduces low level ozone - affects plant growth
- is irritating to eyes, nose and throat
i) sunlight breaks down NO2 NO2 ——> NO + Oii) ozone is produced O + O2 ——> O3
Pollutant gasesPollutant gasesOxides of nitrogen NOx - NO, N2O and NO2
Origin nitrogen and oxygen combine under high temperature conditionsnitrogen combines with oxygen N2(g) + O2(g) ——> 2NO(g)nitrogen monoxide is oxidised 2NO(g) + O2(g) ——> 2NO2(g)
Effect photochemical smog - irritating to eyes, nose and throatproduces low level ozone - affects plant growth
- is irritating to eyes, nose and throat
i) sunlight breaks down NO2 NO2 ——> NO + Oii) ozone is produced O + O2 ——> O3
Removal 2CO(g) + 2NO(g) ——> N2(g) + 2CO2(g)
Pollutant gasesPollutant gasesUnburnt hydrocarbons CxHy
Origin insufficient oxygen for complete combustion
Effect toxic and carcinogenic (causes cancer)
Removal catalyst aids complete combustion C8H18(g) + 12½O2(g) ——> 8CO2(g) + 9H2O(l)
Homogeneous CatalysisHomogeneous Catalysis
Action • catalyst and reactants are in the same phase• reaction proceeds through an intermediate species of lower energy• there is usually more than one reaction step• transition metal ions are often involved - oxidation state changes
ExampleAcids Esterificaton
Conc. H2SO4 catalyses the reaction between acids and alcohols CH3COOH + C2H5OH CH3COOC2H5 + H2O
NB Catalysts have NO EFFECT ON THE POSITION OF EQUILIBRIUM but they do affect the rate at which equilibrium is reached
Homogeneous CatalysisHomogeneous Catalysis
Action • catalyst and reactants are in the same phase• reaction proceeds through an intermediate species of lower energy• there is usually more than one reaction step• transition metal ions are often involved - oxidation state changes
Homogeneous CatalysisHomogeneous Catalysis
Action • catalyst and reactants are in the same phase• reaction proceeds through an intermediate species with of energy• there is usually more than one reaction step• transition metal ions are often involved - oxidation state changes
ExamplesGases Atmospheric OZONE breaks down naturally O3 ——> O• + O2
- it breaks down more easily in the presence of chlorofluorocarbons (CFC's).
There is a series of complex reactions but the basic process is :-CFC's break down in the presence ofUV light to form chlorine radicals CCl2F2 ——> Cl• + • CClF2
chlorine radicals then react with ozone O3 + Cl• ——> ClO• + O2
chlorine radicals are regenerated ClO• + O ——> O2 + Cl•
Overall, chlorine radicals are not used up so a small amount of CFC's candestroy thousands of ozone molecules before the termination stage.
Transition metal compoundsTransition metal compoundsThese work because of their ability to change oxidation state
1. Reaction between iron(III) and vanadium(III)
The reaction is catalysed by Cu2+
step 1 Cu2+ + V3+ ——> Cu+ + V4+
step 2 Fe3+ + Cu+ ——> Fe2+ + Cu2+
overall Fe3+ + V3+ ——> Fe2+ + V4+
Transition metal compoundsTransition metal compoundsThese work because of their ability to change oxidation state
2. Reaction between I¯ and S2O82-
A slow reaction because REACTANTS ARE NEGATIVE IONS REPULSION
Addition of iron(II) catalyses the reaction
step 1 S2O82- + 2Fe2+ ——> 2SO4
2- + 2Fe3+
step 2 2Fe3+ + 2I¯ ——> 2Fe2+ + I2
overall S2O82- + 2I¯ ——> 2SO4
2- + I2
Auto-catalysisAuto-catalysisOccurs when a product of the reaction catalyses the reaction itself
It is found in the reactions of manganate(VII) with ethandioate
2MnO4¯ + 16H+ + 5C2O42- ——> 2Mn2+ + 8H2O + 10CO2
The titration needs to be carried out at 70°C because the reaction is slow as Mn2+ is formed the reaction speeds up; the Mn2+ formed acts as the catalyst
Activity is affected by ...temperature - it increases until the protein is denaturedsubstrate concentration - reaches a maximum when all sites are blockedpH - many catalysts are amino acids which can be protonatedbeing poisoned - when the active sites become “clogged” with unwanted
ENZYMESENZYMESActionAction enzymes are extremely effective biologically active catalysts
they are homogeneous catalysts, reacting in solution with body fluidsonly one type of molecule will fit the active site “lock and key” mechanismmakes enzymes very specific as to what they catalyse.
ENZYMESENZYMESActionAction enzymes are extremely effective biologically active catalysts
they are homogeneous catalysts, reacting in solution with body fluidsonly one type of molecule will fit the active site “lock and key” mechanismmakes enzymes very specific as to what they catalyse.
AA B B C C
AA Only species with the correct shape can enter the active site in the enzyme
BB Once in position, the substrate can react with a lower activation energy
CC The new products do not have the correct shape to fit so the complex breaks up
ENZYMESENZYMESANIMATED ACTIONANIMATED ACTION
AA Only species with the correct shape can enter the active site in the enzyme
BB Once in position, the substrate can react with a lower activation energy
CC The new products do not have the correct shape to fit so the complex breaks up
CATALYSISCATALYSISThe EndThe End
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