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Chapter 13Chemical Kinetics
Chemistry: A Molecular Approach, 2nd Ed.Nivaldo Tro
Roy KennedyMassachusetts Bay Community College
Wellesley Hills, MA
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Chemical Kinetics
• Chemical kinetics is the study of the factors that affect the rates of chemical reactionsSuch as temperature
• The speed of a chemical reaction is called its reaction rate
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Defining Reaction Rate
• The rate of a chemical reaction is generally measured in terms of how much the concentration of a reactant decreases in a given period of timeor product concentration increases
• For reactants, a negative sign is placed in front of the definition
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Reaction Rate Changes Over Time
• As time goes on, the rate of a reaction generally slows down because the concentration of the reactants
decreases
• At some time the reaction stops, either because the reactants run out or because the system has reached equilibrium
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Reaction Rate and Stoichiometry• In most reactions, the coefficients of the balanced
equation are not all the same
H2 (g) + I2 (g) 2 HI(g)
• For these reactions, the change in the number of molecules of one substance is a multiple of the change in the number of molecules of another for the above reaction, for every 1 mole of H2 used, 1
mole of I2 will also be used and 2 moles of HI made therefore the rate of change will be different
• To be consistent, the change in the concentration of each substance is multiplied by 1/coefficient
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Example 13.1: For the reaction given, the [I] changes from 1.000 M to 0.868 M in the first 10 s. Calculate the
average rate in the first 10 s and the [H+].H2O2 (aq) + 3 I(aq) + 2 H+
(aq) I3(aq) + 2 H2O(l)
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solve the rate equation for the rate (in terms of the change in concentration of the given quantity)
solve the rate equation (in terms of the change in the concentration for the quantity to find) for the unknown value
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Practice – If 2.4 x 102 g of NOBr (MM 109.91 g) decomposes in a 2.0 x 102 mL flask in 5.0 minutes,
find the average rate of Br2 production in M/s2 NOBr(g) 2 NO(g) + Br2(l)
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Factors Affecting Reaction Rate: Nature of the Reactants
• Nature of the reactants means what kind of reactant molecules and what physical condition they are in small molecules tend to react faster than large molecules gases tend to react faster than liquids, which react faster
than solids powdered solids are more reactive than “blocks”
more surface area for contact with other reactantscertain types of chemicals are more reactive than others
e.g. potassium metal is more reactive than sodiumions react faster than molecules
no bonds need to be broken8Tro: Chemistry: A Molecular Approach, 2/e
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Factors Affecting Reaction Rate:Temperature
• Increasing temperature increases reaction ratechemist’s rule of thumb—for each 10 °C rise in
temperature, the speed of the reaction doublesfor many reactions
• There is a mathematical relationship between the absolute temperature and the speed of a reaction discovered by Svante Arrhenius, which will be examined later
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Factors Affecting Reaction Rate:Catalysts
• Catalysts are substances that affect the speed of a reaction without being consumed
• Most catalysts are used to speed up a reaction; these are called positive catalysts catalysts used to slow a reaction are called negative
catalysts.
• Homogeneous = present in same phase
• Heterogeneous = present in different phase
• How catalysts work will be examined later
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Factors Affecting Reaction Rate:Reactant Concentration
• Generally, the larger the concentration of reactant molecules, the faster the reaction increases the frequency of reactant molecule
contactconcentration of gases depends on the partial
pressure of the gas higher pressure = higher concentration
• Concentrations of solutions depend on the solute-to-solution ratio (molarity)
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The Rate Law• The rate law of a reaction is the mathematical
relationship between the rate of the reaction and the concentrations of the reactantsand homogeneous catalysts as well
• The rate law must be determined experimentally!!
• The rate of a reaction is directly proportional to the concentration of each reactant raised to a power
• For the reaction aA + bB products the rate law would have the form given belown and m are called the orders for each reactantk is called the rate constant
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Reaction Order• The exponent on each reactant in the rate law
is called the order with respect to that reactant• The sum of the exponents on the reactants is
called the order of the reaction • The rate law for the reaction
2 NO(g) + O2(g) 2 NO2(g)
is Rate = k[NO]2[O2]
The reaction is
second order with respect to [NO],
first order with respect to [O2],
and third order overall13Tro: Chemistry: A Molecular Approach, 2/e
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Sample Rate Laws
The bottom reaction is autocatalytic because a product affects the rate.Hg2+ is a negative catalyst; increasing its concentration slows the reaction.
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Rate = k[NO][O3]
Solve:
Conceptual Plan:
Relationships:
[NO] = 1.00 x 10−6 M, [O3] = 3.00 x 10−6 M, Rate = 6.60 x 10−6 M/s k, M−1s−1
Given:
Find:
Example: The rate equation for the reaction of NO with ozone is Rate = k[NO][O3]. If the rate is 6.60 x 10−5 M/sec when [NO] =
1.00 x 10−6 M and [O3] = 3.00 x 10−6 M, calculate the rate constant
Rate, [NO], [O3] k
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Practice – The rate law for the decomposition of acetaldehyde is Rate = k[acetaldehyde]2. What is the rate of the reaction when the
[acetaldehyde] = 1.75 x 10−3 M and the rate constant is 6.73 x 10−6 M−1•s−1?
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Finding the Rate Law:the Initial Rate Method
• The rate law must be determined experimentally
• The rate law shows how the rate of a reaction depends on the concentration of the reactants
• Changing the initial concentration of a reactant will therefore affect the initial rate of the reaction
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if for the reaction A → Products
then doubling the initial concentration of A doubles the initial reaction rate
then doubling the initial concentration of A does not change the initial reaction rate
then doubling the initial concentration of A quadruples the initial reaction rate
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Rate = k[A]n
• If a reaction is Zero Order, the rate of the reaction is always the samedoubling [A] will have no effect on the reaction rate
• If a reaction is First Order, the rate is directly proportional to the reactant concentrationdoubling [A] will double the rate of the reaction
• If a reaction is Second Order, the rate is directly proportional to the square of the reactant concentrationdoubling [A] will quadruple the rate of the reaction
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Determining the Rate Law When there Are Multiple Reactants
• Changing each reactant will effect the overall rate of the reaction
• By changing the initial concentration of one reactant at a time, the effect of each reactant’s concentration on the rate can be determined
• In examining results, we compare differences in rate for reactions that only differ in the concentration of one reactant
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Example 13.2: Determine the rate law and rate constant for the reaction NO2(g) + CO(g) NO(g) + CO2(g)
given the data below
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Practice – Determine the rate law and rate constant for the reaction NH4
+ + NO2− N2 + 2 H2O
given the data below
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Half-Life
• The half-life, t1/2, of a reaction is the length of time it takes for the concentration of the reactant to fall to ½ its initial value
• The half-life of the reaction depends on the order of the reaction
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Zero Order Reactions• Rate = k[A]0 = k
constant rate reactions
• [A] = −kt + [A]initial
• Graph of [A] vs. time is straight line with slope = −k and y–intercept = [A]initial
• t ½ = [Ainitial]/2k• When Rate = M/sec, k = M/sec
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First Order Reactions
• Rate = k[A]1 = k[A]
• ln[A] = −kt + ln[A]initial
• Graph ln[A] vs. time gives straight line with slope = −k and y–intercept = ln[A]initial
used to determine the rate constant
• t½ = 0.693/k
• The half-life of a first order reaction is constant
• When Rate = M/sec, k = s–1
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The Half-Life of a First-Order Reaction Is Constant
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Second Order Reactions
• Rate = k[A]2
• 1/[A] = kt + 1/[A]initial
• Graph 1/[A] vs. time gives straight line with slope = k and y–intercept = 1/[A]initial
used to determine the rate constant
• t½ = 1/(k[A0])
• When Rate = M/sec, k = M−1s−1
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Example 13.4: The reaction SO2Cl2(g) SO2(g) + Cl2(g) is first order with a rate constant of 2.90 x 10−4 s−1 at a given set of conditions.
Find the [SO2Cl2] at 865 s when [SO2Cl2]initial = 0.0225 M
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the new concentration is less than the original, as expected
[SO2Cl2]init = 0.0225 M, t = 865, k = 2.90 x 10-4 s−1
[SO2Cl2]
Check:
Solution:
Conceptual Plan:
Relationships:
Given:
Find:
[SO2Cl2][SO2Cl2]init, t, k
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Practice – The reaction Q 2 R is second order in Q. If the initial [Q] = 0.010 M and after 5.0 x 102 seconds
the [Q] = 0.0010 M, find the rate constant
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Graphical Determination of the Rate Law for A Product
• Plots of [A] vs. time, ln[A] vs. time, and 1/[A] vs. time allow determination of whether a reaction is zero, first, or second order
• Whichever plot gives a straight line determines the order with respect to [A]if linear is [A] vs. time, Rate = k[A]0
if linear is ln[A] vs. time, Rate = k[A]1
if linear is 1/[A] vs. time, Rate = k[A]2
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Relationship Between Order and Half-Life
• For a zero order reaction, the lower the initial concentration of the reactants, the shorter the half-life t1/2
= [A]init/2k
• For a first order reaction, the half-life is independent of the concentration t1/2 = ln(2)/k
• For a second order reaction, the half-life is inversely proportional to the initial concentration – increasing the initial concentration shortens the half-life t1/2 = 1/(k[A]init)
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Example 13.6: Molecular iodine dissociates at 625 K with a first-order rate constant of 0.271 s−1. What is the half-life of this
reaction?
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the new concentration is less than the original, as expected
k = 0.271 s−1
t1/2
Check:
Solution:
Conceptual Plan:
Relationships:
Given:
Find:
t1/2k
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Practice – The reaction Q 2 R is second order in Q. If the initial [Q] = 0.010 M and the rate constant is
1.8 M−1•s−1 find the length of time for [Q] = ½[Q]init
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• Changing the temperature changes the rate constant of the rate law
• Svante Arrhenius investigated this relationship and showed that:
R is the gas constant in energy units, 8.314 J/(mol•K)where T is the temperature in kelvins
A is called the frequency factor, the rate the reactant energy approaches the activation energy
Ea is the activation energy, the extra energy needed to start the molecules reacting
The Effect of Temperature on Rate
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Activation Energy and theActivated Complex
• There is an energy barrier to almost all reactions
• The activation energy is the amount of energy needed to convert reactants into the activated complexaka transition state
• The activated complex is a chemical species with partially broken and partially formed bondsalways very high in energy because of its partial
bonds
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The Arrhenius Equation:The Exponential Factor
• The exponential factor in the Arrhenius equation is a number between 0 and 1
• Tt represents the fraction of reactant molecules with sufficient energy so they can make it over the energy barrier the higher the energy barrier (larger activation energy), the fewer
molecules that have sufficient energy to overcome it
• That extra energy comes from converting the kinetic energy of motion to potential energy in the molecule when the molecules collide increasing the temperature increases the average kinetic energy of
the molecules therefore, increasing the temperature will increase the number of
molecules with sufficient energy to overcome the energy barrier therefore increasing the temperature will increase the reaction rate
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Arrhenius Plots• The Arrhenius Equation can be algebraically
solved to give the following form:
this equation is in the form y = mx + bwhere y = ln(k) and x = (1/T)
a graph of ln(k) vs. (1/T) is a straight line
(−8.314 J/mol∙K)(slope of the line) = Ea, (in Joules)
ey–intercept = A (unit is the same as k)
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Example 13.7: Determine the activation energy and frequency factor for the reaction O3(g) O2(g) + O(g)
given the following data:
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Example 13.7: Determine the activation energy and frequency factor for the reaction O3(g) O2(g) + O(g)
given the following data:
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Arrhenius Equation:Two-Point Form
• If you only have two (T,k) data points, the following forms of the Arrhenius Equation can be used:
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Example 13.8: The reaction NO2(g) + CO(g) CO2(g) + NO(g) has a rate constant of 2.57 M−1∙s−1 at 701 K and 567 M−1∙s−1
at 895 K. Find the activation energy in kJ/mol
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most activation energies are tens to hundreds of kJ/mol – so the answer is reasonable
T1 = 701 K, k1 = 2.57 M−1∙s−1, T2 = 895 K, k2 = 567 M−1∙s−1
Ea, kJ/mol
Check:
Solution:
Conceptual Plan:
Relationships:
Given:
Find:
EaT1, k1, T2, k2
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Collision Theory of Kinetics
• For most reactions, for a reaction to take place, the reacting molecules must collide with each other
on average about 109 collisions per second
• Once molecules collide they may react together or they may not, depending on two factors –
1. whether the collision has enough energy to "break the bonds holding reactant molecules together"; and
2. whether the reacting molecules collide in the proper orientation for new bonds to form
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Effective CollisionsOrientation Effect
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Effective Collisions
• Collisions in which these two conditions are met (and therefore lead to reaction) are called effective collisions
• The higher the frequency of effective collisions, the faster the reaction rate
• When two molecules have an effective collision, a temporary, high energy (unstable) chemical species is formed – the activated complex
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Reaction Mechanisms• The probability of more than 3 molecules colliding
at the same instant with the proper orientation and sufficient energy to overcome the energy barrier is negligible
• Most reactions occur in a series of small reactions involving 1, 2, or at most 3 molecules
• Describing the series of reactions that occurs to produce the overall observed reaction is called a reaction mechanism
• Knowing the rate law of the reaction helps us understand the sequence of reactions in the mechanism
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An Example of a Reaction Mechanism• Overall reaction:
H2(g) + 2 ICl(g) 2 HCl(g) + I2(g) • Mechanism:
1. H2(g) + ICl(g) HCl(g) + HI(g)
2. HI(g) + ICl(g) HCl(g) + I2(g)
• The reactions in this mechanism are elementary steps, meaning that they cannot be broken down into simpler steps and that the molecules actually interact directly in this manner without any other steps
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H2(g) + 2 ICl(g) 2 HCl(g) + I2(g)1) H2(g) + ICl(g) HCl(g) + HI(g) 2) HI(g) + ICl(g) HCl(g) + I2(g)
Elements of a MechanismIntermediates
• Notice that the HI is a product in Step 1, but then a reactant in Step 2
• Because HI is made but then consumed, HI does not show up in the overall reaction
• Materials that are products in an early mechanism step, but then a reactant in a later step, are called intermediates
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Molecularity
• The number of reactant particles in an elementary step is called its molecularity
• A unimolecular step involves one particle
• A bimolecular step involves two particlesthough they may be the same kind of particle
• A termolecular step involves three particlesthough these are exceedingly rare in elementary
steps
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Rate Laws for Elementary Steps• Each step in the mechanism is like its own little
reaction – with its own activation energy and own rate law
• The rate law for an overall reaction must be determined experimentally
• But the rate law of an elementary step can be deduced from the equation of the step
H2(g) + 2 ICl(g) 2 HCl(g) + I2(g)1) H2(g) + ICl(g) HCl(g) + HI(g) Rate = k1[H2][ICl]
2) HI(g) + ICl(g) HCl(g) + I2(g) Rate = k2[HI][ICl]
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Rate Laws of Elementary Steps
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Rate Determining Step• In most mechanisms, one step occurs slower than the
other steps• The result is that product production cannot occur any
faster than the slowest step – the step determines the rate of the overall reaction
• We call the slowest step in the mechanism the rate determining step the slowest step has the largest activation energy
• The rate law of the rate determining step determines the rate law of the overall reaction
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Another Reaction Mechanism
The first step in this mechanism is the rate determining step.
The first step is slower than the second step because its activation energy is larger.
The rate law of the first step is the same as the rate law of the overall reaction.
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NO2(g) + CO(g) NO(g) + CO2(g) Rateobs = k[NO2]2
1. NO2(g) + NO2(g) NO3(g) + NO(g) Rate = k1[NO2]2 Slow2. NO3(g) + CO(g) NO2(g) + CO2(g) Rate = k2[NO3][CO] Fast
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Validating a Mechanism
• To validate (not prove) a mechanism, two conditions must be met:
1. The elementary steps must sum to the overall reaction
2. The rate law predicted by the mechanism must be consistent with the experimentally observed rate law
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Mechanisms with a Fast Initial Step
• When a mechanism contains a fast initial step, the rate limiting step may contain intermediates
• When a previous step is rapid and reaches equilibrium, the forward and reverse reaction rates are equal – so the concentrations of reactants and products of the step are relatedand the product is an intermediate
• Substituting into the rate law of the RDS will produce a rate law in terms of just reactants
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An Example
1. 2 NO(g) N2O2(g) Fast
2. H2(g) + N2O2(g) H2O(g) + N2O(g) Slow Rate = k2[H2][N2O2]
3. H2(g) + N2O(g) H2O(g) + N2(g) Fast
k1
k−1
2 H2(g) + 2 NO(g) 2 H2O(g) + N2(g) Rateobs = k [H2][NO]2
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Practice – MechanismDetermine the overall reaction, the rate determining step, the rate law, and identify allintermediates of the following mechanism
1. A + B2 AB + B Slow2. A + B AB Fast
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Catalysts• Catalysts are substances that affect the rate of a
reaction without being consumed
• Catalysts work by providing an alternative mechanism for the reactionwith a lower activation energy
• Catalysts are consumed in an early mechanism step, then made in a later step
mechanism without catalyst
O3(g) + O(g) 2 O2(g) V. Slow
mechanism with catalyst
Cl(g) + O3(g) O2(g) + ClO(g) Fast
ClO(g) + O(g) O2(g) + Cl(g) Slow
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Practice – MechanismDetermine the overall reaction, the rate determining step, the rate law, and identify all catalysts and intermediates of the following mechanism1. HQ2R2 + R− Q2R2
− + HR Fast2. Q2R2
− Q2R + R− Slow
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Catalysts
• Homogeneous catalysts are in the same phase as the reactant particlesCl(g) in the destruction of O3(g)
• Heterogeneous catalysts are in a different phase than the reactant particlessolid catalytic converter in a car’s exhaust system
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