\( 2.5 \, \text{g} \) of a non-volatile, non-electrolyte is dissolved in \( 100 \, \text{g} \) of water at \( 25^\circ \text{C} \). The solution showed a boiling point elevation by \( 2^\circ \text{C} \). Assuming the solute concentration is negligible with respect to the solvent concentration, the vapour pressure of the resulting aqueous solution is ______ mm of Hg (nearest integer).
(Given: Molal boiling point elevation constant of water (\( K_b \)) = \( 0.52 \, \text{K} \cdot \text{kg} \cdot \text{mol}^{-1} \),1 atm pressure = \( 760 \, \text{mm of Hg} \), molar mass of water = \( 18 \, \text{g mol}^{-1} \))
(Given: Molal boiling point elevation constant of water (\( K_b \)) = \( 0.52 \, \text{K} \cdot \text{kg} \cdot \text{mol}^{-1} \),1 atm pressure = \( 760 \, \text{mm of Hg} \), molar mass of water = \( 18 \, \text{g mol}^{-1} \))
Correct Answer: 707
Solution and Explanation
Determine the Molality of the Solution:
The boiling point elevation \( \Delta T_b \) is related to molality (\( m \)) as follows: \[ \Delta T_b = K_b \times m \]
Given:
\[ \Delta T_b = 2^\circ C, \quad K_b = 0.52 \, \text{K kg mol}^{-1} \] \[ m = \frac{\Delta T_b}{K_b} = \frac{2}{0.52} \approx 3.85 \, \text{mol kg}^{-1} \]
Calculate the Moles of Solute:
Since molality \( m \) is defined as moles of solute per kilogram of solvent: \[ \text{moles of solute} = m \times \text{mass of solvent (in kg)} \] Given that the mass of solvent (water) is 100 g or 0.1 kg: \[ \text{moles of solute} = 3.85 \times 0.1 = 0.385 \, \text{moles} \]
Determine the Molar Mass of the Solute:
Given mass of solute = 2.5 g, \[ \text{Molar mass of solute} = \frac{\text{mass of solute}}{\text{moles of solute}} = \frac{2.5}{0.385} \approx 6.49 \, \text{g/mol} \]
Calculate the Vapour Pressure Lowering:
The vapour pressure lowering \( \Delta P \) is given by: \[ \Delta P = P^0 \times \frac{\text{moles of solute}}{\text{moles of solvent}} \] where \( P^0 = 760 \, \text{mm Hg} \) and moles of solvent (water) = \[ \frac{100}{18} \approx 5.56 \, \text{moles}. \]
Calculate \( \Delta P \):
\[ \Delta P = 760 \times \frac{0.385}{5.56} \approx 52.61 \, \text{mm Hg} \]
Calculate the Vapour Pressure of the Solution:
\[ P_{\text{solution}} = P^0 - \Delta P = 760 - 52.61 \approx 707 \, \text{mm Hg} \]
Conclusion:
The vapour pressure of the resulting aqueous solution is approximately \( 707 \, \text{mm Hg} \).
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