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Rate Theories

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Rate Theories Two theories explaining why reactions occur at different rates Transition State Theory Collision These two theories are basically the same! – PowerPoint PPT presentation

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Title: Rate Theories


1
Rate Theories
  • Two theories explaining why reactions occur at
    different rates
  • Transition State Theory
  • Collision
  • These two theories are basically the same!
  • Transition State includes more information

2
Energy Relationships
  • Activation energy (Ea) minimum amount of energy
    needed for reactions to occur
  • Like an energy barrier that separates the
    reactants from products
  • The greater the activation energy, the more
    difficult it will be for the reaction to occur
    ? Slower reaction

3
Activation Energy
  • Reactants do not immediately change into the
    products
  • As reactants come together, an activated complex
    is formed
  • Activated complex is higher in energy than the
    reactants
  • Activation energy difference in energy between
    reactants and activated complex

4
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5
Energy Graph
  • activated complex
  • Energy Ea
  • reactants
  • DE
  • products
  • Reaction Pathway

6
Change in Energy
  • DE for a reaction
  • energy of products energy of reactants
  • DE for a reaction
  • Activation energy reverse direction
    activation energy forward direction

7
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8
CH3NC ? CH3CN
9
Overcoming Activation Energy
  • Molecules are constantly moving
  • This movement is kinetic energy
  • When molecules collide, some of their energy is
    transferred
  • Eventually, two molecules collide with sufficient
    energy to overcome activation energy

10
Making a Reaction Occur
  • Three things are needed for a reaction to occur
  • Molecules must collide
  • Collision must have sufficient energy
  • Molecules must have proper orientation

11
Making a Reaction Occur
  • Effective Collision Ineffective Collision
  • Sufficient
  • Speed ?
  • Molecules are changed Molecules
    remain unchanged
  • Reaction occurs No
    reaction occurs

12
Reaction Mechanisms
  • In many reactions, it is too difficult for all of
    the reactants to collide properly in one step.
  • Most reactions occur in a series of steps
  • Reaction Mechanism step by step description of
    how reaction occurs
  • Deduced from Rate Law and Activation Energy

13
Reaction Mechanisms
  • Made up of a series of single step reactions
  • Reactions that CAN occur in one step
  • Single step reaction also known as Elementary
    reaction
  • Each reaction in the mechanism elementary
    reaction

14
Reaction Mechanisms
  • Three types of elementary reactions
  • Unimolecular ? One reacting molecule
  • A ? C D
  • Bimolecular ? Two reacting molecules
  • 2A ? C D
  • A B ? C D
  • Termolecular ? Three reacting molecules
  • 2A B ? C D

15
Reaction Mechanisms
  • Each step in the mechanism is labeled as fast or
    slow
  • The slow step is the rate determining step
  • The rate law for the reaction can be predicted
    from the slow step
  • This rate law must be compared to EXPERIMENTALLY
    determined rate law

16
Reaction Mechanisms
  • A mechanism is valid IF
  • The steps add up to the original equation
  • The rate law based on the mechanism matches the
    experimental rate law

17
Reaction Mechanisms
  • Coefficient from balanced equation is the
    reaction order

Reaction Rate Law Rxn order (reactants) Rxn Order (overall)
A ? C D Rate kA 1st 1st
A B ? C D Rate kAB 1st 2nd
2A ? C D Rate kA2 2nd 2nd
18
Reaction Mechanisms
  • Consider the reaction
  • NO2 CO ? NO CO2
  • Rate law written from reaction
  • Rate k NO2 CO
  • Rate law determined experimentally
  • Rate k NO22

19
Reaction Mechanisms
  • Reaction NO2 CO ? NO CO2
  • Proposed mechanism
  • 2NO2 ? NO NO3 slow
  • NO3 CO ? NO2 CO2 fast
  • Rate law based on slow step
  • Rate k NO22

20
Reaction Mechanisms
  • Mechanisms can include Intermediates ? compounds
    that do not appear in the overall equation
  • Intermediates can NEVER appear in the rate law.
  • 2NO2 ? NO NO3
  • NO3 CO ? NO2 CO2

21
Reaction Mechanisms
  • If an intermediate is part of the slow step, it
    must be replaced in the rate law with its
    compliment
  • If the first step is fast AND equilibrium, be on
    the lookout for intermediates.

22
Reaction Mechanisms
  • Reaction Cl2 CHCl3 ? HCl CCl4
  • Rate Law Rate k Cl21/2 CHCl3
  • Mechanism
  • Cl2 ??2Cl fast
  • Cl CHCl3 ? HCl CCl3 slow
  • Cl CCl3 ? CCl4 fast

23
Factors Affecting Rate
  • Catalyst substance that changes the rate but is
    not part of the reaction
  • In general, catalysts INCREASE rate
  • Catalysts increase the rate of reaction by
    creating a different reaction pathway
  • The new pathway has a lower activation energy
  • More molecules have sufficient energy

24
Catalysts
  • Energy Diagram
  • uncatalyzed
  • Ea
  • Energy Ea catalyzed
  • reactants
  • DE
  • products
  • Reaction Pathway

25
Catalysts
  • Two types of catalysts
  • Homogeneous ? catalyst in same phase as reactants
  • Heterogeneous ? catalyst in different phase than
    reactants
  • Usually finely divided metals

26
Rate vs. Temperature
  • Reaction rates INCREASE when temperature
    increases. WHY??
  • Increasing the temperature increases the average
    kinetic energy of the molecules.
  • More molecules will have enough energy to
    overcome activation energy

27
Rate vs. Temperature
  • Arrhenius equation summarizes temp rate
    relationship
  • ln k ln A Ea OR k Ae(-Ea/RT)
  • RT
  • A frequency factor Ea activation energy
  • R gas constant k rate constant
  • T temperature (K)

28
Rate vs. Temperature
  • ln k ln A (Ea / RT)
  • Frequency factor constant that describes number
    of effective collisions
  • As activation energy increases, rate constant
    decreases
  • As temperature increases, rate constant increases

29
Rate vs. Temperature
  • We can modify the Arrenhius equation to compare
    the rate constant at different temperatures
  • ln k1 Ea 1 - 1
  • k2 R T2 T1

30
Rate vs. Temperature
  • C2H5Br ? C2H4 HBr
  • Rate constant 2.0 x 10-5 / sec at 650 K
  • Frequency factor 9.58 x 1012 / sec
  • Find the rate constant at 670 K.
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