Chapter 12 PDF - Reaction Rates

Summary

This document is a chapter on reaction rates, chemical kinetics, along with related concepts. It covers topics like the effect of reactant concentration, temperature and nature on reaction rates. A few examples of reactions with their respective rate laws are also included.

Full Transcript

Chapter 12
CHEM 0120
 Reaction Rates
The reaction rate is the speed of a chemical reaction.
It is the increase in molar concentration of product of a reaction
per unit time (or the decrease in molar concentration of reactant
per unit time).

The rate of a reaction is a measure of how fast the reaction
makes products or uses reactants.

The ability to control the speed of a chemical reaction is
important.
2
 Chemical Kinetics
The study of reaction rates, how reaction rates change
under varying conditions, and what molecular events
occur during the overall reaction.

The rate of any given reaction can be affected by numerous
variables:
Concentrations of Reactants or Catalyst
Temperature
Nature of Reactants

3
 Reactant Concentration Affect on Reaction Rate
Generally, the greater the concentration of reactant
molecules, the faster the reaction.
This increases the frequency of reactant molecule contact.
Concentration 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).

4
 Temperature Affect on Reaction Rate
Increasing temperature increases the reaction rate for most
reactions.

The Arrhenius equation is a mathematical relationship
between the absolute temperature and the speed of a
reaction. This relationship will be examined in the next
class.

5
 Nature of the Reactants Affect on Reaction rate
Nature of the reactants refers to what kind of reactant molecules
there are 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 reactants
Certain types of chemicals are more reactive than others.
For example, potassium metal is more reactive than sodium.
Ions react faster than molecules.
No bonds need to be broken.
6
 Defining Rate
Rate is how much a quantity changes
in a given period of time.

The speed at which you walked to
chemistry lecture is a rate:
The distance you walked (feet or
miles) in a given period of time (1
minute or 1 hour)
So, the rate at which you walked
has units of ft/min or mi/hr.
We can further break it down into
different periods of time for
average and instantaneous rates. 7
 Defining Reaction Rate
The rate of a chemical reaction is measured in terms of how
much the concentration of a reactant decreases (or the
product concentration increases) in a given period of time.
Example: H2(g) + I2(g) → 2 HI(g)
For reactants, a negative sign is placed in front of the definition.

The rate of chemical reaction over two time periods can be
written as follows:

8
 Concentrations as a Function of 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. 9
 Average Rate
The average rate is the change in measured concentrations in any
particular time period.
Linear approximation of a curve
The larger the time interval, the more the average rate deviates from
the instantaneous rate.

10
 Instantaneous Rate
The instantaneous rate is the change in concentration at
any one particular time.
Slope at one point of a curve

The instantaneous rate is determined by taking the slope of
a line tangent to the curve at that particular point.
In calculus: first derivative of the function

11
 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 mol of H2 used, 1 mol of I2 will also
be used and 2 mol 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.

12
 Measuring Reaction Rates
To measure the reaction rate you need to be able to
measure the concentration of at least one component in
the mixture at many points in time.

There are two ways of approaching this problem:
– For reactions that are complete in less than 1 hour, it is
best to use continuous monitoring of the concentration.
– For reactions that happen over a very long time,
sampling of the mixture at various times can be used.
13
 Finding the Rate Law
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.

14
 The Effect of Concentration on Reaction Rate
The rate law of a reaction is the mathematical relationship
between the rate of the reaction and the concentrations of the
reactants and homogeneous catalysts as well.
Rate = k [A]n

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 below.
n and m are called the orders for each reactant.
k is called the rate constant. 15
 Dependence of Rate on Concentration
Rate Law: an equation that relates the rate of a reaction to
the concentration of reactants (and catalysts) raised to
various powers.
C
aA + bB → dD + eE C = catalyst
Rate = k[A]m[B]n[C]p

m, n and p are called the orders for each reactant.
k is called the rate constant – a proportionality constant
in the relationship between rate and concentrations.
16
 Reaction Order
The exponent on each reactant in the rate law is called the reaction
order with respect to that reactant, as experimentally determined.

The sum of the exponents on the reactants is called the overall
order of the reaction.

The rate law for the reaction 2 NO(g) + O2(g) → 2 NO2(g)
is as follows:
Rate = k[NO]2[O2]
The reaction is
second order with respect to [NO];
first order with respect to [O2].
The reaction is third order overall.
17
 Reaction Orders
If a reaction is zero order, the rate of the reaction does not change.
Doubling [A] will have no effect on the reaction rate.
Rate law: Rate = k[A]0 = k
If a reaction is first order, the rate is directly proportional to the reactant
concentration.
Doubling [A] will double the rate of the reaction.
Rate law: Rate = k[A]1 = k[A]
If a reaction is second order, the rate is directly proportional to the square of
the reactant concentration.
Doubling [A] will quadruple the rate of the reaction.
Rate law: Rate = k[A]2
18
 Determining the Reaction Order
The reaction order must
be determined from the
experimental data.

19
 Determining the Reaction Order
The reaction order must be determined
from the experimental data.

Example: 2N2O5(g) → 4NO2(g) + O2(g)

Initial [N2O5] Initial rate of disappearance of N2O5
Experiment 1 1.0 x 10-2 mol/L 4.8 x 10-6 mol/(L∙s)
Experiment 2 2.0 x 10-2 mol/L 9.6 x 10-6 mol/(L∙s)

20
Determining the Rate Law with Multiple Reactants
Changing each reactant will affect 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.

Example:

21
 Change of Concentration with Time
For the reaction A + B → products, the rate law
depends on the concentrations of A and B.

An integrated rate law uses calculus to transform a
rate law into a mathematical relationship between
concentration and time.

22
 Integrated Rate Law: First-Order
Rate law:
Rate = k[A]1 = k[A]

Integrated rate law:
ln[A]t = −kt + ln[A]0
[𝐀𝐀]𝒕𝒕
or 𝐥𝐥𝐥𝐥 = −𝒌𝒌𝒌𝒌
[𝐀𝐀]𝟎𝟎

A graph of first order:
ln[A] versus time results in a straight line
where slope = −k
y-intercept = ln[A]initial
23
 Integrated Rate Law: Second-Order
Rate law:
Rate = k[A]2
Integrated rate law:
𝟏𝟏 𝟏𝟏
= 𝒌𝒌𝒌𝒌 +
[𝐀𝐀]𝒕𝒕 [𝐀𝐀]𝟎𝟎

A graph of second order:
1/[A] versus time results in a straight line
where slope = k
y-intercept = 1/[A]initial
24
 Integrated Rate Law: Zero-Order
Rate law:
Rate = k[A]0 = k

Integrated rate law:
[A]t = −kt + [A]0

A graph of zero order:
[A] versus time results in a straight line
where slope = −k
y-intercept = [A]initial
25
Rate Law Relationships

26
 Half-Life of a Reaction
Half-life (t1/2) of a reaction: the time it takes for the
reactant concentration to decrease to one-half of its
initial value.

Reactions:
0.693
First-order: 𝑡𝑡1/2 =
𝑘𝑘
1
Second-order: 𝑡𝑡1/2 =
𝑘𝑘[A]0
[A]0
Zero-order: 𝑡𝑡1/2 =
2𝑘𝑘

27
 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]0/2k

For a first order reaction, the half-life is independent of the
concentration.
t1/2 = 0.693/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]0) 28
 Effect of Temperature on Rate
Changing the temperature changes the rate constant of the rate law

This relationship is given by the Arrhenius equation:
𝒌𝒌 = 𝑨𝑨𝒆𝒆−𝑬𝑬𝒂𝒂 /𝑹𝑹𝑹𝑹
where
T is temperature in Kelvin
R is the gas constant in energy units, 8.314 J/(K · mol)
Ea is the activation energy, the extra energy needed to start the
molecules reacting
A is a constant referred to as the frequency factor
The rate the reactant energy approaches the
activation energy 29
 Potential-Energy Curve
Exothermic reaction. Heat energy is released when the
reaction proceeds in the forward direction.

30
 Activation Energy
There is an energy barrier to almost all reactions.

The activation energy is the amount of energy needed to
convert reactants into the activated complex.
The activated complex is also know as a transition state.

The activated complex is a chemical species with partially
broken and partially formed bonds.
Always very high in energy because of its partial bonds
31
 Energy Profile for the Isomerization of
Methyl Isonitrile
The activation energy is the
difference in energy between the
reactants and the activated complex.
The frequency is the number of
molecules that begin to form the
activated complex in a given period
of time.
As the reaction begins, the C—N
bond weakens enough for the CN
triple bonded group to start to rotate.
The activated complex is a chemical
species with partial bonds. 32
 The Exponential Factor in the Arrhenius equation
The exponential factor in the Arrhenius equation is a number between 0 and 1
It 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;
reaction rate.
33
 A Summary of Temperature and Reaction Rate
The frequency factor is the number
of times that the reactants approach
the activation barrier per unit time.

The exponential factor is the fraction
of the approaches that are successful
in surmounting the activation barrier
and forming products.

The exponential factor increases with
increasing temperature but decreases
with increasing activation energy.

34
 Arrhenius Plots: Experimental Measurements
The Arrhenius equation can be algebraically solved to give
the following form:

𝐸𝐸𝑎𝑎
ln 𝑘𝑘 = ln 𝐴𝐴 −
𝑅𝑅𝑅𝑅

This equation is in the form y = mx + b,
– where y = ln(k) and x = (1/T).

A graph of ln(k) versus (1/T) is a straight line
35
 Arrhenius Equation: Two-Point Form
If you have only two (T,k) data points, the following forms
of the Arrhenius equation can be used:

𝑘𝑘2 𝐸𝐸𝑎𝑎 1 1
ln = −
𝑘𝑘1 𝑅𝑅 𝑇𝑇1 𝑇𝑇2

36
 Example
The rate constant for the formation of hydrogen
iodide from the elements is 2.7 x 10-4 L/(mol s) at
600 K and 3.5 x 10-3 L/(mol s) at 650 K.
A) Find the activation energy.
B) Calculate the rate constant at 700 K.

37
 Collision Theory
Collision Theory of Reaction Rates: a theory that assumes that,
for a reaction to occur, reactant molecules must collide with an
energy greater than some minimum value and with the proper
orientation.
The minimum energy of collision required for two molecules to
react is the activation energy (Ea).

The rate constant (k) for a reaction is dependent upon:
1. The collision frequency
2. The fraction of collisions having a higher energy than Ea
3. The fraction of collision that occur with the reactant molecules
properly oriented.
38
 Effective Collisions: Kinetic Energy Factor

For a collision to lead to
overcoming the energy
barrier, the reacting
molecules must have
sufficient kinetic energy so
that when they collide the
activated complex can
form.

39
 Effective Collisions
Collision frequency: the number of collisions that happen per second

The more collisions there are per second, the more collisions can be
effective and lead to product formation.

The higher the frequency of effective collisions, the faster the
reaction rate.

Collisions in which these two conditions are met (and therefore lead
to reaction) are called effective collisions.

When two molecules have an effective collision, a temporary, high-
energy (unstable) chemical species is formed: the activated complex.
40
 Orientation Factor
The proper orientation results when the atoms are aligned in such
a way that the old bonds can break and the new bonds can form.
The more complex the reactant molecules, the less frequently they
will collide with the proper orientation.

41
 Reaction Mechanisms
Chemical reactions are generally described with a net chemical equation
listing all the reactant molecules and product molecules.
The probability of more than three 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 one, two, or (at
most) three molecules.
Reaction Mechanism: the set of elementary reactions whose overall effect is
given by the net chemical equation.
Knowing the rate law of the reaction helps us understand the sequence of
reactions in the mechanism.

42
 Reaction Mechanism Example
Overall reaction:
H2(g) + 2 ICl(g) → 2 HCl(g) + I2(g) (net chemical equation)

Mechanism:
H2(g) + ICl(g) → HCl(g) + HI(g) (elementary reaction)
HI(g) + ICl(g) → HCl(g) + I2(g) (elementary reaction)

The reactions in this mechanism are elementary reactions, meaning
that they cannot be broken down into simpler steps and that the
molecules actually interact directly in this manner without any
other steps.
43
 Reaction Intermediates
H2(g) + 2 ICl(g) → 2 HCl(g) + I2(g)

H2(g) + ICl(g) → HCl(g) + HI(g)
HI(g) + ICl(g) → HCl(g) + I2(g)

Notice that the HI is a product in step 1, but it is 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 reactants
in a later step are called intermediates.
Reaction intermediates: a species produced during a reaction that does not
appear in the net equation because it reacts in a subsequent step in the
mechanism.
44
 Determining the Rate Equation for an
Elementary Reaction
The number of reactant particles in an elementary step is called its molecularity.

A unimolecular step involves one particle.

A bimolecular step involves two particles.
These two particles may be the same kind of particle.

A termolecular step involves three particles.
These are exceedingly rare in elementary steps.

45
 Rate Equation for an Elementary Reaction
H2(g) + 2 ICl(g) → 2 HCl(g) + I2(g)

1) H2(g) + ICl(g) → HCl(g) + HI(g) Rate =
2) HI(g) + ICl(g) → HCl(g) + I2(g) Rate =

Treat each step in the mechanism like its own reaction with its own Ea and
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.

46
Rate Laws for Elementary Steps
(from Pearson Education, INC.)

47
 Rate-Determining Step
Rate-determining step: the slowest step in the reaction
mechanism

When on step is 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.
The slowest step has the largest activation energy.

The rate law of the rate-determining step determines the
rate law of the overall reaction. 48
 Reaction Mechanism Example
NO2(g) + CO(g) → NO(g) + CO2(g) Rateobs = k[NO2]2

Proposed Mechanism
1. NO2(g) + NO2(g) → NO3(g) + NO(g) Rate = k1[NO2]2 Slow
2. NO3(g) + CO(g) → NO2(g) + CO2(g) Rate = k2[NO3][CO] Fast
The first step is slower than the second
step because its activation energy is larger.
The first step in this mechanism is the
rate-determining step: It is the slowest
step.
The rate law of the first step is the same as
the rate law of the overall reaction.

49
 Criteria for Validating a Mechanism
To validate (not prove) a mechanism, two conditions must
be met:

1. The elementary steps must sum to the overall balanced
chemical reaction.

2. The rate law predicted by the rate-determining step of
the mechanism must be consistent with the
experimentally observed rate law.
50
 Mechanisms with an Initial Fast 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
related and the product is an intermediate.

Substituting into the rate law of the rate-determining
step will produce a rate law in terms of just reactants.
51
 Example of a Mechanism with an Initial Fast Step

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

52
 Catalysts
Catalysts are substances that
affect the rate of a reaction Mechanism without catalyst:
without being consumed.
O3(g) + O(g) → 2 O2(g) V. Slow

Catalysts work by providing
an alternative mechanism for Mechanism with catalyst:
the reaction with a lower
activation energy. Cl(g) + O3(g) ⇌ O2(g) + ClO(g) Fast

ClO(g) + O(g) → O2(g) + Cl(g) Slow
Catalysts are consumed in an
early mechanism step and
then made in a later step.
53
 Factors Affecting Reaction Rate
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 catalysts: all species present
in same phase

Heterogeneous catalysts: species present in
different phase

54
 Catalyst Types
Homogeneous catalysts are in the same phase as the
reactant particles.
Cl(g) in the destruction of O3(g)

Heterogeneous catalysts are in a different phase than the
reactant particles.
Solid catalytic converter in a car’s exhaust system

55
Catalyst Types

56
 Catalytic Hydrogenation Reaction
1. Adsorption: The reactants are adsorbed onto metal surfaces.
2. Diffusion: The reactants diffuse on the surface until they approach each other.
3. Reaction: The reactants react to form the products.
4. Desorption: The products desorb from the surface into the gas phase.

57