Chapter 2 Solutions: Q&A

In this post, questions and answers of class 12 chapter Solutions are provided which included NCERT questions.

1. Calculate the mass percentage of benzene (C₆H₆) and carbon tetrachloride (CCl₄) if 22 g of benzene is dissolved in 122 g of carbon tetrachloride.

Answer: Mass of solution = Mass of C₆H₆ + Mass of CCl₄ = 22 g+122 g= 144 g
Mass % of benzene = 22/144 x 100 =15.28 %
Mass % of CCl₄ = 122/144 x 100 = 84.72 %

2. Calculate the mole fraction of benzene in solution containing 30% by mass in carbon tetrachloride.

Answer: 30% by mass of C₆H₆ in CCl₄ = 30 g C₆H₆ in 100 g solution

Mass of C₆H₆ = 30 g

Mass of CCl₄ = Mass of solution – Mass of C₆H₆ = 100 – 30 = 70 g

No. of moles of C₆H₆ = 30/78 = 0.385

No. of moles of CCl₄ = 70/154 = 0.455

So, the mole fraction of benzene is 0.458

3. Calculate the molarity of each of the following solution:
(a) 30 g of Co(NO₃)₂.6H₂O in 4.3 L of solution
(b) 30 mL of 0.5 M H₂SO₄ diluted to 500 mL

Answer: (a) Mass of Co(NO₃)₂.6H₂O = 30 g

Molar mass of Co(NO₃)₂.6H₂O = 59 + 2(14+3(16)) + 6(2(1)+16) = 291 g mol^-1

Number of moles of Co(NO₃)₂.6H₂O = Given mass/Molar mass = 30/291 = 0.1031 mol

Volume of solution = 4.3 L

Molarity = Number of moles/Volume of solution = 0.1031/4.3 = 0.02397 M = 0.024 M

(b) Molarity of undiluted H₂SO₄ (M₁) = 0.5 M

Volume of undiluted H₂SO₄ (V₁) = 30 ml

Volume of diluted H₂SO₄ solution (V₂) = 500 ml

Molarity of diluted solution (M₂) is calculated as:

M₁V₁=M₂V₂

M₂ = M₁V₁/V₂ = (0.5 x 30)/(500) = 0.03 M

4. Calculate the mass of urea (NH₂CONH₂) required in making 2.5 kg of 0.25 molal aqueous solution.

Answer: Molality = 0.25 m

Mass of solvent = 2.5 Kg

Number of mole of urea = Molality x Mass of solvent (in Kg) = 0.25 x 2.5 = 0.625 mol

Molar mass of urea = 60 g/mol

Mass of urea = No. of mole x Molar mass = 0.625 x 60 = 37.5 g

5. Calculate:

(a) molality

(b) molarity and

(c) mole fraction of KI,

if the density of 20% (m/m) aqueous KI solution is 1·202 g mL^-1.

Answer: Mass of KI in 100 g of the solution = 20 g

Mass of solvent (water) = 100 – 20 = 80 g = 0.080 kg

Mass of solution = 100 g

Density of solution = 1.202 g/ml

Volume of solution = Mass/Density = 100/1.202 = 83.195 ml = 0.0832 L

Molar mass of KI = 39 + 127 = 166 g mol^-1

Molar mass of H₂O = 18 g mol^-1

No. of mole of KI = ^{Given mass}/_{Molar mass} = 20/166 = 0.1204 mol

No. of mole of water = ⁸⁰/₁₈ = 4.44 mol

(a) Molality = ^{No. of mole of KI}/_{Mass of solvent (in Kg)} = 0.1204/0.080 = 1.505 m

(b) Molarity = ^{No. of mole of KI}/_{Volume of solution (in L)} = 0.1204/0.0832 = 1.45 M

(c) Mole Fraction of KI = ^{Mole of KI}/_{Mole of (KI+Water)} = 0.1204/(0.1204+4.44) = 0.0264

6. H₂S, a toxic gas with rotten egg like smell, is used for the qualitative analysis. If the solubility of H₂S in water at STP is 0.195 m, calculate Henry’s law constant.

Answer: Solubility of H₂S gas = 0.195 m = 0.195 mole in 1000 g of water

Mole of H₂S = 0.195 mol

Mole of water = 1000/18 = 55.55 mol

Mole fraction of H₂S, X(H₂S) = Mole of H₂S/Mole of (H₂S + H₂O) = 0.195/(0.195+55.55) = 0.0035

We already know that, Pressure at STP = 0.987 bar

Applying Henry’s law, P = K_H * X(H₂S)

K_H = P/X(H₂S) = 0.987/0.0035 = 282 bar

7. Henry’s law constant for CO₂ in water is 1.67 x 10⁸ Pa at 298 K. Calculate the quantity of CO₂ in 500 mL of soda water when packed under 2.5 atm CO₂ pressure at 298 K.

Answer: K_H = 1.67 x 10⁸ Pa

P(CO₂) = 2.5 atm = 2.5 x 1.01325 x 10⁵ Pa

Applying Henry’s law,

Mole fraction of CO₂, X(CO₂) = P/K_H = (2.5 x 1.01325 x 10⁵)/(1.67 x 10⁸) = 1.517 x 10^-3

For 500 ml of soda water, mole of H₂O = 500/18 =27.78 mol

Mole fraction of CO₂ = Mole of CO₂/Mole of H₂O

Mole of CO₂ = 1.517 x 10^-3 x 27.78 = 42.14 x 10^-3 mol

Mass of CO₂ = 42.14 x 10^-3 x 44 = 1.854 g

8. The vapour pressures of pure liquids A and B are 450 mm and 700 mm of Hg respectively at 350 K. Calculate the composition of the liquid mixture if total vapour pressure is 600 mm of Hg. Also find the composition in the vapour phase.

Answer: Vapour pressure of pure liquid A (P^∘_A) = 450 mm
Vapour pressure of pure liquid B (P^∘_B) = 700 mm
Total vapour pressure of the solution (P) = 600 mm

According to Raoult’s law, P = P^∘_AX_A + P^∘_BX_B = P^∘_AX_A + P^∘_B(1-X_A)

600 = 450X_A + 700(1-X_A)

600 = 700 – 250X_A

X_A = 0.40

X_B = 1 – X_A = 1-0.40 = 0.60

Mole fraction of A = 0.40

Mole fraction of B = 0.60

P_A = P^∘_AX_A = 450 * 0.40 = 180 mm

P_B = P^∘_BX_B = 700 * 0.60 = 420 mm

P_T = P_A + P_B = 180+420 = 600 mm

Mole fraction of A in vapour phase = P_A/P_T = 180/600 = 0.30

Mole fraction of B in vapour phase = P_B/P_T = 420/600 = 0.70

9. Vapour pressure of pure water at 298 K is 23.8 mm Hg. 50 g of urea (NH₂CONH₂) is dissolved in 850 g of water. Calculate the vapour pressure of water for this solution and its relative lowering.

Answer: P^∘(H₂O) = 23.8 mm Hg

Mass of urea (w₂) = 50 g

Mass of water (w₁) = 850 g

Molar mass of urea and water are 60 g/mol and 18 g/mol respectively.

Mole of urea (n₂) = 50/60 = 0.83 mol

Mole of water (n₁) = 850/18 = 47.22 mol

Relative lowering of vapour pressure is 0.017

Now, put P^∘(H₂O) = 23.8 mm Hg in the relative lowering of vapour pressure expression, we get

P_s = 23.39 mm Hg = 23.4 mm Hg

Hence, the vapour pressure of solution is 23.4 mm Hg and its relative lowering is 0.017

10. Boiling point of water at 750 mm Hg is 96.63°C. How much sucrose is to be added to 500 g of water such that it boils at 100°C.

Answer: T^∘_b = 100^∘C

T_b = 96.63^∘C

∆T_b = T^∘_b – T_b = 100 – 96.63 = 3.37^∘C = 3.37 K (Temperature difference is same in both units)

Mass of water (w₁) = 500 g = 0.5 Kg

Molar mass of sugar (M₂) = 342 g/mol

K_b = 0.52 K Kg mol^-1

∆T_b = K_b * m

w₂ = 1108.2 g = 1.11 Kg

Mass of sucrose to be added is 1.11 Kg.

11. Calculate the mass of ascorbic acid (vitamin C, C₆H₈O₆) to be dissolved in 75 g of acetic acid to lower its melting point by 1·5°C. (K_f for CH₃COOH) = 3·9 K kg mol^-1)

Answer: Depression in melting point (∆T_f) = 1.5^∘C = 1.5 K

Mass of acetic acid (w₁) = 75 g = 0.075 Kg

Molar mass of C₆H₈O₆ (M₂) = 176 g/mol

K_f = 3.9 K Kg mol^-1

w₂ = 5.08 g

Mass of ascorbic acid to be dissolved is 5.08 g

12. Calculate the osmotic pressure in pascals exerted by a solution prepared by dissolving 1.0 g of polymer of molar mass 185,000 in 450 mL of water at 37°C.

Answer: Mass of polymer = 1.0 g

Volume of solution = 450 ml = 0.45 L

Molar mass of polymer = 185000 g/mol

Temperature = 37^∘C = (37+273) K = 310 K

Mole of polymer = Mass/Molar mass = 1.0/185000 = 5.41 x 10^-6 mol

R = 8.314 x 10³ Pa L K^-1 mol^-1

Concentration, C = Mole/Volume = (5.41 x 10^-6)/0.45 =12.02 x 10^-6 M

Osmotic pressure, π = C x R x T

π = 12.02 x 10^-6 x 8.314 x 10³ x 310 = 30.979 Pa

Hence, the osmotic pressure is 30.979 Pa

13. Define the terra solution. How many types of solutions are formed? Write briefly about each type with an example.

Answer: A solution is a homogeneous mixture of two or more chemically non-reacting substances.

Types of solutions: There are nine types of solutions. Examples:

Gaseous solutions: (a) Gas in gas Air, mixture of O₂ and N₂, etc.
(b) Liquid in gas Water vapour
(c) Solid in gas Camphor vapours in N₂ gas, smoke etc.

Liquid solutions: (a) Gas in liquid CO₂ dissolved in water (aerated water), and 02 dissolved in water, etc.
(b) Liquid in liquid Ethanol dissolved in water, etc.
(c) Solid in liquid Sugar dissolved in water, saline water, etc.

Solid solutions: (a) Gas in solid Solution of hydrogen in palladium
(b) Liquid in solid Amalgams, e.g., Na-Hg
(c) Solid in solid Gold ornaments (Cu/Ag with Au)

14. Suppose a solid solution is formed between two substances, one whose particles are very large and the other whose particles are very small. What type of solid solution is this likely to be?

Answer: The solution likely to be formed is interstitial solid solution.

15. Define the following terms:
(i) Mole fraction
(ii) Molality
(iii) Molarity
(iv) Mass percentage

Answer: (i) Mole fraction: It is defined as the ratio of the number of moles of the solute(or solvent) to the total number of moles in the solution. If B is the number of moles of solute dissolved in A moles of solvent, then

(ii) Molality: It is defined as the number of moles of a solute present in 1000g (1kg) of a solvent.

Molality = ^{Number of moles of solute}/_{Mass of solvent (in Kg)}

Note: Molality is considered better way of expressing concentration of solutions, as compared to molarity because molality does not change with change in temperature since the mass of solvent does not vary with temperature.

(iii) Molarity: It is defined as the number of moles of solute present in one litre of solution.

Molarity = ^{Number of moles of solute}/_{Volume of solution (in L)}

Note: Molarity is the most common way of expressing concentration of a solution in laboratory. However, it has one disadvantage. It changes with temperature because volume of a solution alters due to expansion and contraction of the liquid with temperature.

(iv) Mass percentage: It is the amount of solute in grams present in 100g of solution.

Mass percentage = (^{Mass of solute}/_{Mass of solution}) x 100

16. Concentrated nitric acid used in the laboratory work is 68% nitric acid by mass in aqueous solution. What should be the molarity of such a sample of acid if the density of the solution is 1·504 g mL^-1 ?

Answer: Mass of HNO₃ in solution = 68 g
Molar mass of HNO₃ = 63 g mol^-1
Mass of solution = 100 g
Density of solution = 1·504 g mL^-1

Volume of solution = Mass of solution/Density of solution = 100/1.504 = 66.5 ml = 0.0665 L

Mole of HNO₃ = Mass/Molar mass = 68/63 = 1.08 mol

Molarity of HNO3 = No. of mole/Volume of solution (L) = 1.08/0.0665 = 16.24 M

17. A solution of glucose in water is labelled as 10% w/w, what would be the molality and mole fraction of each component in the solution? If the density of solution is 1.2 g mL^-1, then what shall be the molarity of the solution?

Answer: 10% w/w glucose solution means 10 g glucose in 100 g of solution.

Mass of glucose = 10 g

Mass of solution = 100 g

Mass of water = 100 – 10 = 90 g = 0.090 Kg

Mole of glucose (n₂) = 10/180 = 0.055 mol

Mole of water (n₁) = 90/18 = 5 mol

Molality = ^{Mole of glucose}/_{Mass of water (Kg)} = ^0.055/_0.090 = 0.617 m

Mole fraction of glucose = ⁿ²/_(n1+n2) = ^0.055/_(5+0.055) = 0.011

Mole fraction of water = 1-Mole fraction of glucose = 1-0.011 = 0.989

Volume of solution = Mass/Density = 100/1.2 = 83.33 ml = 0.0833 L

Molarity = Moles/Volume (L) = 0.055/0.0833 = 0.66 M

18. How many mL of 0.1 M HCl are required to react completely with 1 g mixture of Na₂CO₃ and NaHCO₃ containing equimolar amounts of both?

Answer: Let x g of Na₂CO₃ and (1-x) g NaHCO₃ is present in the mixture.

Molar mass of Na₂CO₃ = 106 g/mol

Molar mass of NaHCO₃ = 84 g/mol

No. of mole of Na₂CO₃ = x/106 mol

No. of mole of NaHCO₃ = (1-x)/84 mol

As given that the mixture contains equimolar amounts of both Na₂CO₃ and NaHCO₃, so

Mole of Na₂CO₃ = Mole of NaHCO₃

On solving, x = 0.558 g

Mass of Na₂CO₃ and NaHCO₃ are 0.558 g and 0.442 g respectively.

No. of mole of Na₂CO₃ = 0.558/106 = 0.00526 mol

No. of mole of NaHCO₃ = 0.442/84 = 0.00526 mol

Now, the balanced chemical equation of Na₂CO₃ and NaHCO₃ with HCl are:

Na₂CO₃ + 2 HCl → 2NaCl + H₂O + CO₂

NaHCO₃ + HCl → NaCl + H₂O + CO₂

From the balanced chemical equation, 1 mol Na₂CO₃ reacts with 2 mol HCl while 1 mol NaHCO₃ reacts with 1 mol HCl.

So, 0.00526 mol Na₂CO₃ reacts with HCl = 2 x 0.00526 = 0.01052 mol

and 0.00526 mol NaHCO₃ reacts with HCl = 0.00526 mol

Total mole of HCl required = 0.01052 + 0.00526 = 0.01578 mol

Molarity of HCl = 0.1 M

Volume of HCl required = ^{Mole of HCl}/_{Molarity of HCl} = ^0.01578/_0.1 = 0.1578 L = 157.8 ml

19. Calculate the percentage composition in terms of mass of a solution obtained by mixing 300 g of a 25% and 400 g of a 40% solution by mass.

Answer: Mass of one component = 25% of 300 = 75 g

Mass of other component = 40% of 400 = 160 g

After mixing both the solution,

Total mass of solute = 75 + 160 = 235 g

Total mass of solution = 300 + 400 = 700 g

Mass % of solute in the final solution = (235/700) x 100 = 33.57 %

Mass % of solvent in the final solution = 100 – 33.57 = 66.43 %

20. An antifreeze solution is prepared from 222.6 g of ethylene glycol, (C₂ H₆O₂ ) and 200 g of water. Calculate the molality of the solution. If the density of the solution is 1.072 g mL^-1, then what shall be the molarity of the solution?

Answer: Mass of ethylene glycol = 222.6 g

Molar mass of ethylene glycol = 62 g/mol

No. of mole of ethylene glycol = 222.6/62 = 3.59 mol

Mass of solvent = 200 g = 0.2 Kg

Molality = Mole of ethylene glycol/Mass of solvent = 3.59/0.2 = 17.95 m

Mass of solution = Mass of (solute + solvent) = 222.6 + 200 = 422.6 g

Volume of solution = Mass/Density = 422.6/1.072 = 394.21 ml = 0.39421 L

Molarity = Mole of ethylene glycol/Volume of solution = 3.59/0.39421 = 9.11 M

21. A sample of drinking water was found to be severely contaminated with chloroform (CHCl₃), supposed to be a carcinogen. The level of contamination was 15 ppm (by mass).
(i) Express this in percent by mass.
(ii) Determine the molality of chloroform in the water sample.

Answer: 15 ppm means 15 parts in million (10⁶) by mass in the solution.

(i) Mass percent = (15*100)/10⁶ = 15 x 10^-4 %

(ii) As only 15 g CHCl₃ is present in 10⁶ g of solution. Mass of solvent = 10⁶ g = 10³ Kg

Molar mass of CHCl₃ = 119.5 g/mol

No. of mole of CHCl₃ = 15/119.5 = 0.126 mol

Molality = ^{No. of mole of CHCl₃}/_{Mass of solvent (Kg)} = 0.126/10³ = 1.26 x 10^-4 m

22. What role does the molecular interaction play in solution of alcohol in water?

Answer: In case of alcohol as well as water, the molecules are interlinked by intermolecular hydrogen bonding. However, the hydrogen bonding is also present in the molecules of alcohol and water in the solution but it is comparatively less than both alcohol and water. As a result, the magnitude of attractive forces tends to decrease and the solution shows positive deviation from Raoult’s Law. This will lead to increase in vapour pressure of the solution and also decrease in its boiling point.

23. Why do gases always tend to be less soluble in liquids as the temperature is raised?

Answer: When gases are dissolved in water, it is accompanied by a release of heat energy, i.e., process is exothermic. When the temperature is increased, according to Le-Chatelier’s Principle, the equilibrium shifts in backward direction, and thus gases becomes less soluble in liquids.

24. State Henry’s law and mention some of its important applications.

Answer: Henry’s law: The solubility of a gas in a liquid at a particular temperature is directly proportional to the pressure of the gas in equilibrium with the liquid at that temperature.
or
The partial pressure of a gas in vapour phase is proportional to the mole fraction of the gas (x) in the solution. p = K_H.x
where K_H is Henry’s law constant.

Applications of Henry’s law:

(i) In order to increase the solubility of CO₂ gas in soft drinks and soda water, the bottles are normally sealed under high pressure. Increase in pressure increases the solubility of a gas in a solvent according to Henry’s Law. If the bottle is opened by removing the stopper or seal, the pressure on the surface of the gas will suddenly decrease. This will cause a decrease in the solubility of the gas in the liquid i.e. water. As a result, it will rush out of the bottle producing a hissing noise or with a fizz.

(ii) As pointed above, oxygen to be used by deep sea divers is generally diluted with helium in order to reduce or minimise the painful effects during decompression.

(iii) As the partial pressure of oxygen in air is high, in lungs it combines with haemoglobin to form oxyhaemoglobin. In tissues, the partial pressure of oxygen is comparatively low. Therefore, oxyhaemoglobin releases oxygen in order to carry out cellular activities.

25. The partial pressure of ethane over a solution containing 6.56 × 10^-3 g of ethane is 1 bar. If the solution contains 5.00 × 10^-2 g of ethane, then what shall be the partial pressure of the gas?

Answer: We know that m = K_H * P

Case 1: 6.56*10^-3 = K_H * 1 ….(i)

Case 2: 5.00*10^-2 = K_H * P …..(ii)

From (i) K_H = 6.56*10^-3

and From (ii) K_H = 5.00*10^-2/P

So, 6.56*10^-3 = 5.00*10^-2/P

On solving, P = 0.762 bar

Hence, the partial pressure of the gas is 0.762 bar.

Read more: Chapter 1 Solid State Q and A

26. According to Raoult’s law, what is meant by positive and negative deviation and how is the sign of ∆_solH related to positive and negative deviations from Raoult’s law?

Answer: Solutions having vapour pressures more than that expected from Raoult’s law are said to exhibit positive deviation. In these solutions solvent – solute interactions are weaker and ∆_solH is positive because stronger A – A or B – B interactions are replaced by weaker A – B interactions. Breaking of the stronger interactions requires more energy & less energy is released on formation of weaker interactions. So, overall ∆_sol H is positive. Similarly ∆_solV is positive i.e. the volume of solution is some what more than sum of volumes of solvent and solute. So there is expansion in volume on solution formation.

Similarly, in case of solutions exhibiting negative deviations, A – B interactions are stronger than A-A&B-B. So weaker interactions are replaced by stronger interactions so , there is release of energy i.e. ∆_sol H is negative.

27. An aqueous solution of 2% non-volatile solute exerts a pressure of 1·004 bar at the boiling point of the solvent. What is the molecular mass of the solute?

Answer: P° (for water) = 1.013 bar, P_s = 1.004 bar

2% non-volatile solute means 2 g solute in 100 g solution (or 98 g solvent)

Mass of solute (w_B) = 2 g

Mass of water (w_A) = 98 g

Molar mass of water (M_A) = 18 g/mol

According to Raoult’s law,

On solving, M_B = 41 g mol^-1

Hence, the molar mass of the solute is 41 g mol^-1.

28. Heptane and octane form an ideal solution. At 373 K, the vapour pressures of the two liquid components are 105.2 kPa and 46.8 kPa respectively. What will be the vapour pressure of a mixture of 26.0 g of heptane and 35.0 g of octane?

Answer: Vapour pressure of pure heptane = 105.2 kPa

Vapour pressure of pure octane = 46.8 kPa

Molar mass of heptane (C₇H₁₄) = 100 g mol^-1

Molar mass of octane (C₈H₁₆) = 114 g mol^-1

Mass of heptane = 26 g

Mass of octane = 35 g

Mole of heptane = Mass/Molar mass = 26/100 = 0.26 mol

Mole of octane = Mass/Molar mass = 35/114 = 0.307 mol

Total mole = Mole of (heptane + octane) = 0.26 + 0.307 = 0.567 mol

Mole fraction of heptane = Mole of heptane/Total mole = 0.26/0.567 = 0.458

Mole fraction of octane = 1 – Mole fraction of heptane = 1 – 0.458 = 0.542

Vapour pressure of heptane = 105.2 x 0.458 = 48.18 kPa

Vapour pressure of octane = 46.8 x 0.542 = 25.36 kPa

Vapour pressure of the mixture = V.P of (heptane + octane) = 48.18 + 25.36 = 73.54 kPa

Hence, the vapour pressure of the mixture is 73.54 kPa

29. The vapour pressure of water is 12.3 kPa at 300 K. Calculate vapour pressure of 1 molal solution of a non-volatile solute in it.

Answer: 1 molal solution of a non-volatile solute means 1 mol of non-volatile solute in 1000 g of solvent (water).

No. of mole of solute = 1 mol

No. of mol of solvent = 1000/18 = 55.55 mol

Total mole = 1 + 55.55 = 56.55 mol

Mole fraction of non-volatile solute, X₂ = Mole of solute/Total mole = 1/56.55 = 0.0177

Now, (P°-P_s)/P° = X₂

(12.3-P_s)/12.3 = 0.0177

P_s = 12.08 kPa

Hence, the vapour pressure is 12.08 kPa.

30. Calculate the mass of a non-volatile solute (molecular mass 40 g mol^-1) that should be dissolved in 114 g of octane to reduce its pressure to 80%.

Answer: P° = 1 atm, w_A = 114 g, M_A = 114 g/mol M_B = 40 g/mol, P_s = 0.8 atm (1 atm pressure reduced to 80%)

On solving, w_B = 10 g

Hence, the mass of non-volatile solute is 10 g.

31. A solution containing 30g of non-volatile solute exactly in 90 g of water has a vapour pressure of 2.8 kPa at 298 K. Further, 18g of water is then added to the solution and the new of vapour pressure becomes 2.9 kPa at 298 K. Calculate
(i) molar mass of the solute.
(ii) vapour pressure of water at 298 K.

Answer:

32. A 5% solution (by mass) of cane sugar in water has freezing point of 271 K. Calculate the freezing point of 5% glucose in water if freezing point of pure water is 273.15 K.

Answer: Case 1: 5% solution of cane sugar (molar mass: 342 g/mol) means 5 g cane sugar in 100 g solution (or 95 g solvent).

T_f = 271K and T°_f = 273.15 K

∆T_f = T°_f – T_f = 273.15 – 271 = 2.15 K

Mole of cane sugar = 5/342 = 0.015 mol

Mass of solvent = 95 g = 0.095 Kg

Molality of cane sugar, m = Moles of cane sugar/Mass of solvent = 0.015/0.095 = 0.158 m

Now, ∆T_f = K_f*m

Putting values, K_f = ∆T_f/m = 2.15/0.158 = 13.608 K Kg mol^-1

Case 2: 5% solution of glucose (molar mass: 180 g/mol) means 5 g glucose in 100 g solution (or 95 g solvent).

Mole of glucose = 5/180 = 0.0278 mol

Mass of solvent = 95 g = 0.095 Kg

Molality of glucose, m = 0.0278/0.095 = 0.293 m

∆T_f = K_f*m = 13.608 * 0.293 = 3.99 K

∆T_f = T°_f – T_f

3.99 = 273.15 – T_f

T_f = 269.16 K

Hence, the freezing point of 5% glucose solution is 269.16 K.

33. Suggest the most important type of intermolecular attractive interaction in the following pairs:
(i) n-hexane and n-octane
(ii) I₂ and CCl₄.
(iii) NaCl0₄ and water
(iv) methanol and acetone
(v) acetonitrile (CH₃CN) and acetone (C₃H₆O)

Answer: (i) Both w-hexane and n-octane are non-polar. Thus, the intermolecular interactions will be London dispersion forces.
(ii) Both I₂ and CCl₄ are non-polar. Thus, the intermolecular interactions will be London dispersion forces.
(iii) NaClO₄ is an ionic compound and gives Na⁺ and ClO₄^– ions in the Solution. Water is a polar molecule. Thus, the intermolecular interactions will be ion-dipole interactions.
(iv) Both methanol and acetone are polar molecules. Thus, intermolecular interactions will be dipole-dipole interactions.
(v) Both CH₃CN and C₃H₆O are polar molecules. Thus, intermolecular interactions will be dipole-dipole interactions.

34. Based on solute solvent interactions, arrange the following in order of increasing solubility in n-octane and explain. Cyclohexane, KCl, CH₃OH, CH₃CN.

Answer: n-octane (C₈H₁₈) is a non-polar liquid and solubility is governed by the principle that like dissolve like. Keeping this in view, the increasing order of solubility of different solutes is:
KCl < CH₃OH < CH₃C=N < C₆H₁₂ (cyclohexane).

35. Amongst the following compounds, identify which are insoluble, partially soluble and highly soluble in water?
(i) phenol (ii) toluene (iii) formic acid (iv) ethylene glycol (v) chloroform (vi) pentanol

Answer: (i) Phenol (having polar – OH group) – Partially soluble.
(ii) Toluene (non-polar) – Insoluble.
(iii) Formic acid (form hydrogen bonds with water molecules) – Highly soluble.
(iv) Ethylene glycol (form hydrogen bonds with water molecules) Highly soluble.
(v) Chloroform (non-polar)- Insoluble.
(vi) Pentanol (having polar -OH) – Partially soluble.

36. Two elements A and B form compounds having formula AB₂ and AB₄. When dissolved in 20g of benzene (C₆H₆), 1 g of AB₂ lowers the freezing point by 2.3 K whereas 1.0 g of AB₄ lowers it by 1.3 K. The molar depression constant for benzene is 5.1 K kg mol^-1. Calculate atomic masses of A and B.

Answer: Mass of solute (AB₂) = 1 g

Mass of solute (AB₄) = 1 g

Mass of solvent = 20 g = 0.020 Kg

∆T_f (AB₂) = 2.3 K

∆T_f (AB₄) = 1.3 K

Using the equation,

where, M₂ is the molar mass of solute, w₂ is mass of solute and w₁ is mass of solvent in Kg.

So, molar mass of AB₂ and AB₄ are 110.87 g/mol and 196.15 g/mol respectively.

Let the atomic mass of A and B be p and q respectively.

Then, molar mass of AB₂ = p+2q = 110.87 …..(i)

and molar mass of AB₄ = p+4q = 196.15 …..(ii)

On solving the equations (i) and (ii), we get

p = 25.59 g/mol and q = 42.64 g/mol

Hence, the atomic mass of A and B are 25.59 g/mol and 42.64 g/mol respectively.

37. At 300 K, 36 g glucose present per litre in its solution has osmotic pressure of 4·98 bar. If the osmotic pressure of the solution is 1·52 bar at the same temperature, what would be its concentration?

Answer: Case 1: T = 300 K, w₂ = 36 g, M₂ = 180 g/mol, V = 1 L, π = 4.98 bar

Mole of glucose, n = 36/180 = 0.2 mol

π = CRT = (n/V)RT

4.98 = 0.2 RT

RT = 24.9

Case 2: T = 300 K (same as case 1), π = 1.52 bar

π = CRT

C = π/RT = 1.52/24.9 = 0.061 M

So, the concentration of the solution is 0.061 M.

38. If the density of lake water is 1·25 g mL-1, and it contains 92 g of Na⁺ ions per kg of water, calculate the molality of Na⁺ ions in the lake.

Answer: Mass of Na⁺ ions= 92 g

Atomic mass of Na = 23 g/mol

Mass of solvent = 1 Kg

No. of mole of Na⁺ ions = 92/23 = 4 mol

Molality = No. of mole/Mass of solvent = 4/1 = 4 m

39. If the solubility product of CuS is 6 x 10^-16, calculate the maximum molarity of CuS in aqueous solution.

Answer: CuS ⇌ Cu²⁺ + S^2-

Let the solubility be s M

So, K_sp = [Cu²⁺][S^2-]

6 x 10^-16 = (s)(s)

s = √(6 x 10^-16) = 2.45 x 10^-8 M

Hence, the maximum molarity of CuS is 2.45 x 10^-8 M.

40. Calculate the mass percentage of aspirin (C₉H₈O₄) in acetonitrile (CH₃CN) when 6.5g of C₉H₈O₄ is dissolved in 450 g of CH₃CN.

Answer: Mass of aspirin = 6.5 g

Mass of acetonitrile = 450 g

Mass of solution = 450 + 6.5 = 456.5 g

Mass percent = (^{Mass of aspirin}/_{Mass of solution}) x 100 = (6.5/456.5) x 100 = 1.424%

41. Nalorphene (C₁₉H₂₁NO₃), similar to morphine, is used to combat withdrawal symptoms in narcotic users. Dose of nalorphene generally given is 1.5 mg. Calculate the mass of 1.5 x 10^-3 m aqueous solution required for the above dose.

Answer: Mass of nalorphene = 1.5 mg = 1.5 x 10^-3 g

Molar mass of nalorphene = 311 g/mol

Mole of nalorphene = Mass/Molar mass = (1.5 x 10^-3)/311 = 4.823 x 10^-6 mol

Molality of nalorphene = 1.5 x 10^-3 m

Mass of solvent (Kg) = Mole of nalorphene/Molality of nalorphene = (4.823 x 10^-6)/(1.5 x 10^-3) = 0.0032153 Kg = 3.2153 g

Mass of solution = Mass of nalorphene + Mass of solvent = (1.5 x 10^-3) + 3.2153 = 3.2168 g = 3.22 g

Hence, the mass of aqueous solution is 3.22 g.

42. Calculate the amount of benzoic acid (C₆H₅COOH) required for preparing 250 mL of 0· 15 M solution in methanol.

Answer: Molarity = 0.15 M

Volume of solution = 250 ml = 0.25 L

Mole of benzoic acid = Molarity x Volume of solution = 0.15 x 0.25 = 0.0375 mol

Molar mass of benzoic acid = 122 g/mol

Mass of benzoic acid = Mole x Molar mass = 0.0375 x 122 = 4.575 g

43. The depression in freezing point of water observed for the same amount of acetic acid, trichloroacetic acid and trifluoroacetic acid increases in the order given above. Explain briefly.

Answer: Fluorine being more electronegative than chlorine has the highest electron withdrawing inductive effect. Thus, trifluoracetic acid is the strongest, trichloroacetic acid is second most and acetic acid is the weakest acid due to absence of any electron withdrawing group.

Thus, CF₃COOH ionizes to the largest extent while CH₃COOH ionizes to minimum extent in water. Greater the extent of ionization greater is the depression in freezing point. Hence, the order of depression in freezing point will be CH₃COOH < CCl₃COOH < CF₃COOH.

44. Calculate the depression in the freezing point of water when 10g of CH₃CH₂CHClCOOH is added to 250g of water. K_a = 1.4 x 10^-3 and K_f = 1.86 K kg mol^-1.

Answer: Mass of solute (CH₃CH₂CHClCOOH) = 10 g

Molar mass of CH₃CH₂CHClCOOH = 4 × 12 + 7 × 1 + 1 × 35.5 + 2 × 16 = 48 + 7 + 35.5 + 32 = 122.5 g mol^-1

Mole of solute = Mass/Molar mass = 10/122.5 = 0.0816 mol

Mass of solvent = 250 g = 0.25 Kg

Molality = Mole of solute/Mass of solvent (Kg) = 0.0816/0.25 =0.326 m

Let α be the degree of dissociation of CH₃CH₂CHClCOOH, then

Total no. of moles after dissociation = 1 – α + α + α = 1 + α
Van’t Hoff factor, i = ^{Total no. of moles after dissociation}/_{No. of moles before dissociation}

i = ^1+α/₁ = 1 + α = 1 + 0.0655 = 1.0655
Hence, the depression in the freezing point of water, ΔT_f = i x K_f x m = 1.0655 × 1.86 kg mol^-1 × 0.326 mol kg^-1 = 0.65K

45. 19.5g of CH₂FCOOH is dissolved in 500g of water. The depression in the freezing point of water observed is 1.0°C. Calculate the van’s Hoff factor and dissociation constant of fluoroacetic acid.

Answer: w₁ = 500 g = 0.5 kg, w₂ = 19.5 g, K_f = 1.86 K kg mol^-1, ΔT_f = 1 K
Molar mass of CH₂FCOOH (M₂) = 24 + 3 + 19 + 32 = 78 g mol^-1
ΔT_f = i K_f m

46. Vapour pressure of water at 293 K is 17·535 mm Hg. Calculate the vapour pressure of water at 293 K when 25 g of glucose is dissolved in 450 g of water.

Answer: wB = 25 g, MB = 180 g/mol, wA = 450 g, MA= 18 g/mol P° = 17.535 mm Hg

47. Henry’s law constant for the molality of methane in benzene at 298 K is 4.27 x 10⁵ mm Hg. Calculate the solubility of methane in benzene at 298 K under 760 mm Hg.

Answer: P = 760 mm Hg, K_H = 4.27 × 10⁵ mm Hg (at 298 K)
According to Henry’s law, p = K_H * X
X = P/K_H = ⁷⁶⁰/_4.27×10⁵ = 177.99 × 10^-5 = 178 × 10^-5
Hence, the mole fraction of methane in benzene is 178 × 10^-5.

48. 100g of liquid A (molar mass 140 g mol^-1) was dissolved in 1000g of liquid B (molar mass 180g mol^-1). The vapour pressure of pure liquid B was found to be 500 torr. Calculate the vapour pressure of pure liquid A and its vapour pressure in the solution if the total vapour pressure of the solution is 475 torr.

Answer: Number of moles of liquid A, n_A = Mass/Molar mass = 100/140 = 0.714 mol

Number of moles of liquid B, n_B = Mass/Molar mass = 1000/180 mol = 5.556 mol

Total moles, (n_A + n_B) = 0.714 + 5.556 = 6.27 mol

Mole fraction of A, X_A = Mole of A/Total moles = 0.714/6.27 = 0.114

Mole fraction of B, X_B = 1 – 0.114 = 0.886

Vapour pressure of pure liquid B, P°_B = 500 torr

Therefore, vapour pressure of liquid B in the solution, P_B = P°_B * X_B = 500 * 0.886 = 443 torr

Total vapour pressure of the solution, P_total = 475 torr

So, Vapour pressure of liquid A in the solution, P_A = P_total – P_B = 475 – 443 = 32 torr

Now, P_A = P°_A * X_A  

P°_A = P_A/X_A = 32/0.114 = 280.7 torr

Hence, the vapour pressure of pure liquid A is 280.7 torr.

49. Vapour pressures of pure acetone and chloroform at 328 K are 741.8 mm Hg and 632.8 mm Hg respectively. Assuming that they form ideal solution over the entire range of composition, plot P_total, P_chloroform and P_acetone as a function of X_acetone. The experimental data observed for different compositions of mixtures is:

100 * Xacetone	0	11.8	23.4	36.0	50.8	58.2	64.5	72.1
Pacetone/mmHg	0	54.9	110.1	202.4	322.7	405.9	454.1	521.1
Pchloroform/mmHg	632.8	548.1	469.4	359.7	257.7	193.6	161.2	120.7

Plot this data also on the same graph paper. Indicate whether it has positive deviation or negative deviation from the ideal solution.

Answer:

100 * Xacetone	0	11.8	23.4	36.0	50.8	58.2	64.5	72.1
Pacetone/mmHg	0	54.9	110.1	202.4	322.7	405.9	454.1	521.1
Pchloroform/mmHg	632.8	548.1	469.4	359.7	257.7	193.6	161.2	120.7
Ptotal/mmHg	632.8	603.1	579.7	562.4	580.9	600.0	615.9	642.5

It can be observed from the graph that the plot for the P_total of the solution curves downwards. Therefore, the solution shows negative deviation from the ideal behaviour.

50. Benzene and toluene form ideal solution over the entire range of composition. The vapour pressure of pure benzene and toluene at 300 K are 50.71 mm Hg and 32.06 mm Hg respectively. Calculate the mole fraction of benzene in vapour phase if 80g of benzene is mixed with 100g of toluene.

Answer: Molar mass of benzene (C₆H₆) = 78g mol^-1

Molar mass of toluene (C₆H₅CH₃ ) = 92 g mol^-1

No. of moles present in 80 g of benzene = 80/78 mol = 1.026 mol

No. of moles present in 100 g of toluene = 100/92 mol = 1.087 mol

Total moles = Mole of (benzene + toluene) = 1.026 + 1.087 = 2.113 mol

Mole fraction of benzene, X_C6H6, = Mole of benzene/Total mole = 1.026/2.113 = 0.486

Mole fraction of toluene, X_C6H5CH3 = 1-X_C6H6 = 1 – 0.486 = 0.514

It is given that vapour pressure of pure benzene, P°(C₆H₆) = 50.71 mm Hg

Vapour pressure of pure toluene, P°(C₆H₅CH₃) = 32.06 mm Hg

So, Partial vapour pressure of benzene, P_C6H6 = X_C6H6 × P°(C₆H₆) = 0.486 × 50.71 = 24.645 mm Hg

and Partial vapour pressure of toluene, P_C6H5CH3 = X_C6H5CH3 × P°(C₆H₅CH₃) = 0.514 × 32.06 = 16.479 mm Hg

Total vapour pressure of solution P_total = 24.645 + 16.479 = 41.124 mm Hg

Mole fraction of benzene in vapour phase = ^{X_C6H6×P°_C6H6}/_Ptotal = ^0.486×50.71/_41.124 = 0.599

51. The air is a mixture of a number of gases. The major components are oxygen and nitrogen with an approximate proportion of 20% is to 79% by volume at 298 K. The water is in equilibrium with air at a pressure of 10 atm. At 298 K if Henry’s law constants for oxygen and nitrogen are 3.30 x 10⁷ mm and 6.51 x 10⁷ mm respectively, calculate the composition of these gases in water.

Answer: Percentage of oxygen (O₂) in air = 20%

Percentage of nitrogen (N₂) in air = 79%

Also, it is given that water is in equilibrium with air at a total pressure of 10 atm, i.e., (10 × 760) mm = 7600 mm.

Therefore, partial pressure of oxygen, P(O₂) = (20 x 7600)/100 = 1520 mm Hg

Partial pressure of nitrogen, P(N₂) = (79 x 7600)/100 = 6004 mm Hg

Now, according to Henry’s law, P = K_H.X

For oxygen, mole fraction of O₂, X(O₂) = P/K_H= 1520/(3.30 x 10⁷) = 4.61 x 10^-5

For nitrogen, mole fraction of N₂, X(N₂) = P/K_H= 6004/(6.51 x 10⁷) = 9.22 x 10^-5

Hence, the mole fractions of oxygen and nitrogen in water are 4.61 × 10^-5 and 9.22 × 10^-5 respectively.

52. Determine the amount of CaCl₂ (i = 2.47) dissolved in 2.5 litre of water such that its osmotic pressure is 0.75 atm at 27°C.

Answer: π = 0.75 atm, V = 2.5 L, i = 2.47, T = (27 + 273)K = 300K, R = 0.0821 L atm K^-1mol^–1
Molar mass of CaCl₂ = 111 g mol ^-1

π = i CRT

C = π/iRT = 0.75/(2.47×0.0821×300) = 0.0123 M

No of moles of CaCl₂ = Concentration x Volume (L) = 0.0123 x 2.5 = 0.0375 mol

Mass of CaCl₂ = Mole x Molar mass = 0.0375 x 111 = 3.413 g

Hence, the required amount of CaCl₂ is 3.413 g.

53. Determine the osmotic pressure of a solution prepared by dissolving 25 mg of K₂SO₄ in 2 litre of water at 25°C, assuming that it is completely dissociated.

Answer: (i) Calculation of Van’t Hoff factor (i):

(ii) Calculation of osmotic pressure (π):

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