A and B react together to form an equilibrium mixture - AQA - A-Level Chemistry - Question 9 - 2020 - Paper 2

From the question, it states that:

• C = 0.020 mol
• B = 0.30 mol
• Volume of solution = 350 cm³ = 0.35 dm³.

First, we determine concentrations at equilibrium:

For C: ( ext{Concentration of C} = \frac{0.020}{0.35} = 0.0571 ext{ mol dm⁻³})

For B: ( ext{Concentration of B} = \frac{0.30}{0.35} = 0.8571 ext{ mol dm⁻³})

Then we use the expression for Kc for the reaction:

The units of Kc can be derived from its expression: Given:

Without specifying units:

• [C] has units of mol dm⁻³
• [B] has units of mol dm⁻³. So,

In aqueous solutions, the concentration of water is usually much greater than that of the other reactants. Thus, it can be considered effectively constant in the equilibrium expression because it doesn't significantly change. This assumption simplifies the reaction expression.

Given K = 37.0 and the concentration of ClCH₂CHO (which can be calculated):

• Initial amount of ClCH₂CHO = ( \frac{4.71 g}{78.5 g/mol} \approx 0.060 \text{ mol} ).
• Therefore, the equilibrium concentration for ClCH₂(COH)₂ can be calculated: $C = \sqrt{K \times (\text{initial conc.})} = \sqrt{37.0 \times (0.060)} \approx 1.17 ext{ mol dm}^{-3}.$

1. A curly arrow from the lone pair of the oxygen on water to the carbonyl carbon in ClCH₂CHO, creating a tetrahedral intermediate.
2. A curly arrow from the bond between the carbonyl carbon and the pi bond to re-establish the double bond with the oxygen, producing ClCH₂(OH) and moving the electron density onto the oxygen.

The reaction of water with ethanal is slower due to the electron-donating effect of the alkyl group, which makes the carbonyl carbon less electrophilic compared to chloroethanal. Hence, this results in a decreased rate of nucleophilic attack by water.