1. Collision Theory Section 6.1 (continued)

2. Collisions Vital for chemical change Provides the energy required for a particle to change Brings the reactants into contact As particles approach each other, there is a repulsion between the electron clouds of the particles

3. Collisions The collision must have enough kinetic energy to overcome the repulsion in order for a reaction to occur Frequently energy is also required to break some of the bonds before a reaction can take place Therefore, not all collisions result in a reaction

4. Activation Energy Activation energy is the minimum amount of energy required for a reaction E a has units of kJ mol -1 Varies greatly from reaction to reaction

5. Requirements for a Reaction to Occur The two particles involved must: Collide with each other The collision must be energetic enough to overcome the activation energy of the reaction (KE > E a ) The collision must overcome the steric factor, i.e. be in the correct orientation.

6. Steric Factor/orientation Molecules have parts that are arranged in a certain pattern For a collision to occur that leads to a reaction, the parts have to “match” with the reactants This contact must be in a particular way Very important factor for large organic molecules

8. Increase Collision Rate Anything that increases the collision rate increases the rate of the reaction Concentration/pressure Surface area Temperature Presence of a catalyst Light

9. Concentration/Pressure Increase the concentration of the reactants and more collisions will occur Increasing the pressure for reacting gases is like increasing the concentration

10. Surface Area Especially important in a reaction that involves substances in phases that do not mix, like a solid with a liquid, or a gas with a liquid An increase in the surface area in contact will increase the collision rate

12. Maxwell-Boltzmann Energy Distribution Curve A curve describing the distribution of velocities or kinetic energies among the atoms or molecules of an ideal gas Often used to explain the effects of a temperature change or the presence of a catalyst on the rate of a chemical reaction

14. More The area under the curve represents the total number of particles, so in a closed system this area is constant Increasing the temperature causes more collisions, but more importantly it increases the proportion of molecules with KE > E a

15. More The average energy of the particles is proportional to the temperature in Kelvin

16. Catalyst Catalyst: a substance which, when present in relatively small amounts, increases the rate of a chemical reaction but which is not consumed during the reaction A catalyst provides a new reaction pathway with a lower activation energy This means that a greater number of collisions will have the required energy to react

18. Maxwell-Boltzman curve with and without a catalyst.

19. Efficiency of a Catalyst The efficiency of a catalyst decreases with time It becomes inactive due to: Impurities in the reaction mixture Side reactions Its surface becomes coated and unavailable for activity

20. Light Some chemical reactions are brought about by exposure to light The reactant particles absorb light energy that then initiates the reaction Many chemicals are stored in brown glass containers so light can't come in contact with the molecules easily