Since the solution is ideal, Raoult’s law is applicable.
Let vapour pressures of pure components be:
$$ P_A^\circ = P_A,\quad P_B^\circ = P_B $$
Initial solution:
Moles of A = 3, moles of B = 1
Total moles = 4
Mole fractions:
$$ x_A = \frac{3}{4},\quad x_B = \frac{1}{4} $$
Total vapour pressure:
$$ P = x_A P_A + x_B P_B $$
$$ \frac{3}{4}P_A + \frac{1}{4}P_B = 500 $$
Multiplying by 4:
$$ 3P_A + P_B = 2000 \quad \text{(Equation 1)} $$
After adding 1 mol of A:
Moles of A = 4, moles of B = 1
Total moles = 5
New mole fractions:
$$ x_A = \frac{4}{5},\quad x_B = \frac{1}{5} $$
New vapour pressure = 500 + 20 = 520 mm Hg
Applying Raoult’s law again:
$$ \frac{4}{5}P_A + \frac{1}{5}P_B = 520 $$
Multiplying by 5:
$$ 4P_A + P_B = 2600 \quad \text{(Equation 2)} $$
Subtract Equation (1) from Equation (2):
$$ (4P_A + P_B) - (3P_A + P_B) = 2600 - 2000 $$
$$ P_A = 600 $$
Substitute $P_A = 600$ in Equation (1):
$$ 3(600) + P_B = 2000 $$
$$ P_B = 200 $$
Therefore, vapour pressure of B in pure state is 200 mm Hg.
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