Advertisements
Advertisements
प्रश्न
Derive Ostwald’s dilution law for the CH3COOH.
Derive Ostwald’s dilution law equation for weak acid.
Advertisements
उत्तर
i. Consider an equilibrium of the weak acid CH3COOH that exists in solution partly as the undissociated species CH3COOH and partly H+ and CH3COO– ions. Then
\[\ce{CH3COOH_{(aq)} ⇌ H^+_{ (aq)} + CH3COO^-_{ (aq)}}\]
ii. The acid dissociation constant is given as:
`K_a = ([H^+][CH_3COO^-])/[[CH_3COOH]]` ....(1)
iii. Suppose 1 mol of acid CH3COOH is initially present in volume V dm3 of the solution. At equilibrium, the fraction dissociated would be α, where α is the degree of dissociation of the acid. The fraction of an acid that remains undissociated would be (1 − α).
| \[\ce{CH3COOH_{(aq)}⇌ H^+_{ (aq)} + CH3COO^-_{ (aq)}}\] | |||
| The amount present at equilibrium (mol) | (1 – α) | α | α |
| Concentration at equilibrium (mol dm−3) | `(1 - α)/V` | `α/V` | `α/V` |
iv. Thus, at equilibrium [CH3COOH] = `(1 - α)/V` mol dm–3,
[H+] = [CH3COO−] = `α/V` mol dm–3
v. Substituting these in equation (1),
`K_a = (α/V α/V)/((1 - α)/V) = α^2/(1 - α V)` ...(2)
vi. If c is the initial concentration of CH3COOH in mol dm–3 and V is the volume in dm3 mol–1 then c = `1/"V"`. Replacing `1/"V"` in equation (2) by c,
we get
`K_a = (α^2c)/(1 - α)` ...(3)
vii. For the weak acid CH3COOH, α is very small, or (1 − α) ≅ 1. With this equation (2) and (3) becomes:
`K_a = α^2/V` and Ka = α2c ...(4)
α = `sqrt((K_a)/c)` or α = `sqrt(K_a. V)` ...(5)
Equation (5) implies that the degree of dissociation of a weak acid (CH3COOH) is inversely proportional to the square root of its concentration or directly proportional to the square root of the volume of the solution containing 1 mol of the weak acid.
