collision theory and activation energy unit 3: chemical kinetics and equilibrium
TRANSCRIPT
Review: Chemical Reaction Generic Format of reaction
5 different types of chemical reactions
A + B C + D
Reactants Products
1) Synthesis
2) Decomposition
3) Single Displacement
4) Double Displacement
5) Combustion
Review: Kinetic Molecular Theory Used to explain many observations and chemical events!
All matter is made up of microscopic-sized particles (atoms, ions, molecules)
These particles are in constant motion (possess kinetic energy)
There is space between the particles (speed and spacing determine the physical state of matter)
Adding energy increases the speed of the moving particles (thus inc kinetic energy)
How do reactions occur?
In order for a chemical reaction to take place, the In order for a chemical reaction to take place, the reactants must come in contact and collide!!!!!reactants must come in contact and collide!!!!!
The collision transfers kinetic energy needed to break the necessary bonds so that new bonds can be formed.
Collision Theory
Turns out…… By calculating how many collisions are taking place per
second and how quickly product is being produced… chemists learned that most collisions are not successful (no product formed)
To think that reactant particles collide and products are automatically produced is over simplified.
There must be other requirements for a collision to be successful!
The Collision Theory is an explanation of what is necessary for a
chemical reaction to occur. When a chemical reaction takes place, the
reactant particles must meet two conditions (or requirements) during collision for the collisions to be successful:
1. Proper orientation
2. Particles must collide with a certain minimum amount of energy, called activation energy.
o Particles must collide with the proper geometry or orientation for atoms to come in direct contact and form the chemical bonds of the products.
1. Orientation
2. Activation Energy Particles must collide with a certain
minimum amount of energy, called activation energy (Ea).
This energy is required to break chemical bonds in the reactants.
Note: The energy of each particle is not important, it is the energy of the collision.
Potential Energy Diagram:
We can represent the increase in potential energy during a chemical reaction using a potential energy diagram
The kinetic energy of reactants is transferred to potential energy as the reactants collide
“The hill” The hill represents the activation energy that
must be overcome for the reaction to occur “high hill” slow rate of reaction “low hill” fast rate of reaction
Top of hill is called “change over point” There is a chemical species that exists here is
referred to as “activated complex” Activated complex
Neither reactant or product Partial bonds, highly unstable
If both of these conditions are not met, particles will merely collide and bounce off one another without forming products.
Some collisions are successful…. Although, the percentage of successful collisions
is extremely small, chemical reactions still take place at a reasonable rate because there are so many collisions per second between reactant particles!
Reaction Mechanism:
Converting reactants to products often involves more then one step…as you know!
Each step is called an elementary reaction Molecules formed during elementary
reactions are called reaction intermediates (neither reactants nor products)
Example: 2NO + O2 2NO2
Step 1: NO + O2 NO3
Step 2: NO3 +NO 2NO2
The Rate Determining Step: In multi-step reactions there can be 2 or more
elementary reactions…. There is always one reaction that is slowest …this
determines the overall rate of reaction Thus, the slowest elementary reactions is called the
rate determining reaction.
Catalysts:
Works by lowering the activation energy of a reaction so that a larger fraction of reactants have sufficient energy to react
They do this by providing an alternative reaction mechanism
For example: A + B AB (no catalyst)
With catalyst: Step 1: A + catalyst A-cat Step 2: A-cat + B AB + catalyst Overall: A + B AB
Both steps are faster then the original, uncatalyzed reaction
Catalyst remains unchanged in the end
Real life catalyst example:
Manganese dioxide (a black powder) will catalyze the breakdown of hydrogen peroxide.
2H2O2 (aq) → 2H2O(l) + O2 (g) (uncatalyzed) With catalyst:
Car exhaust pipes use catalytic converters to get rid of some of the nasty gases from the engines.