Molecularity & Rate Determining Step
Rate-determining step & intermediates
- A chemical reaction can only go as fast as the slowest part of the reaction
- So, the rate-determining step is the slowest step in the reaction
- If a reactant appears in the rate-determining step, then the concentration of that reactant will also appear in the rate equation
- For example, the rate equation for the reaction below is rate = k[CH3Br][OH-]
CH3Br + OH- → CH3OH + Br-
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- This suggests that both CH3Br and OH- take part in the slow rate-determining step
- Molecularity is the number of reactant particles that participate in the rate-determining step
- This reaction is a bimolecular reaction
- Unimolecular: one species involved in the rate-determining step
- Bimolecular: two species involved in the rate-determining step
- The intermediate is derived from substances that react together to form it in the rate-determining step
- For example, for the reaction above the intermediate would consist of CH3Br and OH-
The intermediate formed from the species that are involved in the rate-determining step (and thus appear in the rate equation)
Exam Tip
Intermediates do not feature in rate equations. Instead, the chemicals required to make the intermediate feature in the rate equation
Identifying the rate-determining step
- The rate-determining step can be identified from a rate equation given that the reaction mechanism is known
- For example, propane (CH3CH2CH3) undergoes bromination under alkaline solutions
- The overall reaction is:
CH3CH2CH3 + Br2 + OH- → CH3CH2CH2Br + H2O + Br-
- The reaction mechanism is:
Reaction mechanism for the bromination of propane under alkaline conditions
- The rate equation is:
Rate = k[CH3CH2CH3][OH-]
- From the rate equation, it can be deduced that only CH3CH2CH3 and OH- are involved in the rate-determining step and not bromine (Br2)
- CH3CH2CH3 and OH- are only involved in the first step of the reaction mechanism, therefore the rate-determining step is:
- CH3CH2CH3 + OH- → CH3CH2CH2- + H2O