AS/A-Level Chemistry - Reaction mechanism

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AS/A-Level Chemistry - Reaction mechanism

AReaction mechanism

July 6, 2021

In A-Level Chemistry, we look at the rate-determining step to see what is the actual reaction:

Most reactions have what is called a reaction mechanism. This shows the series of reactions that occur in a sequence of steps
The slowest of which controls the rate of the reaction; this is known as the rate-determining step.
The reactants that are involved in the rate-determining step are present in the rate equation
Any step that occurs after the rate-determining step will not affect the rate of the reaction; hence the reactants involved will not appear in the rate equation.

For example:

The reaction between 2-chloro-2-methylpropane and KOH react as follows:

(CH₃)CCl+ OH^-⇨ (CH₃)COH+ Cl^-

The orders of the reactants are as follows:

[(CH₃)CCl] – First Order
[OH^-] – Zero Order

This means that the rate equation is: rate = k[(CH₃)CCl]

Therefore only (CH₃)CCl can be present in the rate-determining step. There must be at least two steps in the mechanism as OH- is not present in the first step. An example of a mechanism could be:

(rate-determining step: (CH3)CCl changes to Cl^- and (CH3)C⁺; then second step is Cl- and (CH3)C+ react to form final products of (CH3)COH and Cl^- )

Reactions Involving Different Molar Quantities

Given the reaction:

2NO +O₂ ⇨ 2NO₂

And the rate equation:

Rate= k[NO]²

It shows you the rate-determining step has 2 moles of NO present due to the power of two and without O₂; thus a mechanism could be:

2NO ⇨ N₂O₂

N₂O₂+ O₂ ⇨ 2NO₂

Another example:

CO + NO₂→ CO₂+ NO

If this reaction occurred in a single step, its rate law would be:

rate=k [NO₂] [CO]

However, experiments show that the rate equation is:

rate=k[NO₂]²

the experimental rate law is second-order, suggesting that the reaction rate is determined by a step in which two NO₂ molecules react, and therefore the CO molecule must enter at another, faster step. A possible mechanism that explains the rate equation is:

2NO₂→NO₃+NO (slow step, rate-determining)

NO₃+CO→NO₂+CO₂ (fast step)

Since the first step is the slowest, and the entire reaction must wait for it, it is the rate-determining step. We can picture the rate-determining step to be like the narrowest point in an hourglass; it is the “bottleneck” point of the reaction that determines how quickly reactants can become products.

If the first step in a mechanism is rate-determining, it is easy to find the rate law for the overall expression from the mechanism. If the second or a later step is rate-determining, determining the rate law is slightly more complicated.

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Drafted by Eunice (Chemistry)

References:

https://courses.lumenlearning.com/boundless-chemistry/chapter/reaction-mechanisms/