Chapter 14

Chapter 14: Chemical Kinetics

Rate = $\frac{\text{Concentration Change}}{\text{Time Change}}$
2 N2O5 → 4NO2 + O2
Rate of formation for NO2: $\frac{\Delta [NO_2]}{\Delta t} = 3.7\times 10^{-5} M s^{-1}$
Rate for formation for O2: $9.00\times 10 ^{-6} M s^{-1}$
Rates must be positive
General rate of reaction
- Not formation or decomposition, but the rate of the entire reaction
- Use stoichiometry to make sure that everything is equal to each other
- Get one rate of reaction
  - Take each of the terms and divide it by the stoichiometry
Instantaneous rate: rate of reaction at a single point in time
- It is the slope tangent to the curve

How the reaction proceeds over the entirety of the reaction
aA + bB → products
- Rate Law: $\text{Rate} = k[A]^m[B]^n$
  - These exponents tell us how sensitive the reaction is to changes in concentration
  - These exponents must be experimentally determined
    - This is because there are sequential steps for the reaction
  - The larger the exponent, the more sensitive it is to changes in concentration
3 common reaction orders that we can think about
- We mean exponents by orders (m/n = 0, 1, 2)
  - Technically they can go higher or negative, but that is beyond the scope of General Chemistry II
- If n = 0, the change in concentration has no effect on the rate
- If n = 1, the rate is directly proportional to the concentration
- If n = 2, the rate is proportional to the square of the concentration
Overall reaction order: sum exponents
- $\text{Rate} = k[A]^2[B]^1, \text{rate} = 3$

Initial rates: start of reaction
- Change concentration and see the effect on the rate