NVAMediumJEE 2023Raoult's Law & Vapour Pressure

JEE Chemistry 2023 Question with Solution

The vapour pressure of 30% (w/v)30\%\ (w/v) aqueous solution of glucose is \hspace{2cm} mm Hg\text{mm Hg} at 25C25^\circ\mathrm{C}.

[Given: The density of 30% (w/v)30\%\ (w/v) aqueous solution of glucose is 1.2 gcm31.2\ \mathrm{g\,cm^{-3}} and vapour pressure of pure water is 24 mm Hg24\ \mathrm{mm\ Hg}.]

[Molar mass of glucose = 180 gmol1180\ \mathrm{g\,mol^{-1}}]

Answer

Correct answer:23

Step-by-step solution

Standard Method

Given: 30% (w/v)30\%\ (w/v) glucose solution, density =1.2 gcm3= 1.2\ \mathrm{g\,cm^{-3}}, vapour pressure of pure water =24 mm Hg= 24\ \mathrm{mm\ Hg}, molar mass of glucose =180 gmol1= 180\ \mathrm{g\,mol^{-1}}.

Find: Vapour pressure of the solution.

Interpret 30% (w/v)30\%\ (w/v) solution: 30 g30\ \mathrm{g} of glucose is present in 100 mL100\ \mathrm{mL} of solution.

Mass of solution:

Mass of solution=1.2×100=120 g\text{Mass of solution} = 1.2 \times 100 = 120\ \mathrm{g}

Mass of water:

Mass of water=12030=90 g\text{Mass of water} = 120 - 30 = 90\ \mathrm{g}

Moles of glucose and water:

nglucose=30180=0.167 moln_{\text{glucose}} = \frac{30}{180} = 0.167\ \mathrm{mol} nwater=9018=5 moln_{\text{water}} = \frac{90}{18} = 5\ \mathrm{mol}

Mole fraction of water:

Xwater=55+0.1670.967X_{\text{water}} = \frac{5}{5 + 0.167} \approx 0.967

Apply Raoult's law:

Psolution=Xwater×PwaterP_{\text{solution}} = X_{\text{water}} \times P^\circ_{\text{water}} Psolution=0.967×2423.2 mm HgP_{\text{solution}} = 0.967 \times 24 \approx 23.2\ \mathrm{mm\ Hg}

Nearest integer value:

Psolution23 mm HgP_{\text{solution}} \approx 23\ \mathrm{mm\ Hg}

Therefore, the vapour pressure of the solution is 23 mm Hg23\ \mathrm{mm\ Hg}.

Quick Tip

Given: The solute is non-volatile glucose.

Find: Vapour pressure of the solution.

Use Raoult's law directly after finding the mole fraction of the solvent. The key idea is that only water contributes to vapour pressure, so

P=XsolventPP = X_{\text{solvent}} P^\circ

Compute the mass of water from density and total volume first, then convert both solute and solvent to moles. After obtaining Xwater0.967X_{\text{water}} \approx 0.967, multiply by 24 mm Hg24\ \mathrm{mm\ Hg} to get approximately 23.2 mm Hg23.2\ \mathrm{mm\ Hg}, which gives 2323 as the required integer value.

Common mistakes

  • Treating 30% (w/v)30\%\ (w/v) as 30 g30\ \mathrm{g} glucose in 100 g100\ \mathrm{g} solution is incorrect because (w/v)(w/v) refers to mass of solute per 100 mL100\ \mathrm{mL} of solution. First use the given density to convert volume of solution into mass.

  • Using the mole fraction of glucose instead of the mole fraction of water is incorrect because glucose is non-volatile and does not contribute to vapour pressure. Raoult's law here uses XwaterX_{\text{water}}, not XglucoseX_{\text{glucose}}.

  • Subtracting vapour pressure lowering directly without calculating moles is incorrect because vapour pressure depends on mole fraction, not mass fraction. Convert masses into moles before applying Raoult's law.

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