CBSE · NCERT · Class 12 Chemistry · Chapter 1

NCERT Solutions: Class 12 Chemistry Chapter 1 - Solutions

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Chapter-wise NCERT intext questions and exercise answers for Solutions, grounded in the official textbook.

Questions are taken verbatim from the NCERT textbook; answers were grounded against the chapter's content during generation. Items needing review are marked.
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Exercises 40
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1Exercises40 questions
Q.1.1Define the term solution. How many types of solutions are formed? Write briefly about each type with an example.v
Solution

A solution contains solute and solvent uniformly mixed. The solvent may be gas, liquid or solid and the solute may also be gas, liquid or solid. Examples include gas in gas: air; liquid in gas: moist air; solid in gas: camphor in air; gas in liquid: oxygen in water; liquid in liquid: ethanol in water; solid in liquid: sugar in water; gas in solid: hydrogen in palladium; liquid in solid: amalgam; solid in solid: brass.

Answer:

A solution is a homogeneous mixture of two or more components. Depending on the physical states of solute and solvent, nine types are possible.

Q.1.2Give an example of a solid solution in which the solute is a gas.v
Solution

In this solid solution, palladium is the solid solvent and hydrogen gas is the solute absorbed in the metal lattice.

Answer:

Hydrogen dissolved in palladium is an example.

Q.1.3Define the following terms : (i) Mole fraction (ii) Molality (iii) Molarity (iv) Mass percentage.v
Solution

For component i, mole fraction xi = ni/Σn. Molality m = moles of solute/kg of solvent. Molarity M = moles of solute/litre of solution. Mass percentage = (mass of component/mass of solution) x 100.

Answer:

Mole fraction is moles of a component divided by total moles; molality is moles of solute per kg solvent; molarity is moles of solute per litre solution; mass percentage is mass of component per 100 mass units of solution.

Q.1.4Concentrated nitric acid used in 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?v
Solution

Take 100 g solution. It contains 68 g HNO3 = 68/63 = 1.079 mol. Volume of 100 g solution = 100/1.504 = 66.49 mL = 0.06649 L. Molarity = 1.079/0.06649 = 16.23 M.

Answer:

16.23 M.

Q.1.5A 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 the solution is 1.2 g mL^-1, then what shall be the molarity of the solution?v
Solution

In 100 g solution, glucose = 10 g and water = 90 g. Moles glucose = 10/180 = 0.0556 mol. Molality = 0.0556/0.090 = 0.617 m. Moles water = 90/18 = 5.00 mol, so xglucose = 0.0556/(0.0556 + 5.00) = 0.0110 and xwater = 0.989. Volume of 100 g solution = 100/1.2 = 83.33 mL = 0.08333 L. Molarity = 0.0556/0.08333 = 0.666 M.

Answer:

Molality = 0.617 m; mole fraction of glucose = 0.0110 and of water = 0.989; molarity = 0.666 M.

Q.1.6How many mL of a 0.1 M HCl are required to react completely with 1 g mixture of Na2CO3 and NaHCO3 containing equimolar amounts of both?v
Solution

For acid neutralisation, Na2CO3 + 2HCl → 2NaCl + H2O + CO2 and NaHCO3 + HCl → NaCl + H2O + CO2. Let the mixture contain x mol Na2CO3 and x mol NaHCO3. Its mass is 106x + 84x = 190x = 1 g, so x = 1/190 mol. Total HCl needed = 3x = 3/190 = 0.01579 mol. Volume of 0.1 M HCl = 0.01579/0.1 = 0.1579 L = 158 mL.

Answer:

158 mL.

Q.1.7A solution is obtained by mixing 300 g of 25% solution and 400 g of 40% solution by mass. Calculate the mass percentage of the resulting solution.v
Solution

Solute in 300 g of 25% solution = 75 g. Solute in 400 g of 40% solution = 160 g. Total solute = 235 g and total solution = 700 g. Mass percentage = 235 x 100/700 = 33.6%.

Answer:

33.6% by mass.

Q.1.8An antifreeze solution is prepared from 222.6 g of ethylene glycol (C2H6O2) 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?v
Solution

Molar mass of ethylene glycol = 62 g mol^-1. Moles = 222.6/62 = 3.59 mol. Mass of water = 0.200 kg, so molality = 3.59/0.200 = 17.9 m. Total mass = 422.6 g. Volume = 422.6/1.072 = 394.2 mL = 0.3942 L. Molarity = 3.59/0.3942 = 9.10 M.

Answer:

Molality = 17.9 m; molarity = 9.10 M.

Q.1.9A 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.v
Solution

15 ppm by mass means 15 parts per 10^6 parts solution. Percent by mass = 15/10^6 x 100 = 0.0015%. In 1 kg water sample, mass of CHCl3 is approximately 15 mg = 0.015 g. Moles CHCl3 = 0.015/119.5 = 1.26 x 10^-4 mol. Molality ≈ 1.26 x 10^-4 m.

Answer:

(i) 0.0015% by mass; (ii) 1.26 x 10^-4 m.

Q.1.10What role does the molecular interaction play in a solution of alcohol and water?v
Solution

Alcohol and water molecules can form hydrogen bonds with one another. These solute-solvent interactions make lower alcohols highly soluble in water. However, the interactions differ from alcohol-alcohol and water-water interactions, so mixtures may show deviations from ideality.

Answer:

Hydrogen bonding between alcohol and water controls miscibility and causes non-ideal behaviour.

Q.1.11Why do gases always tend to be less soluble in liquids as the temperature is raised?v
Solution

For most gases, dissolving in a liquid releases heat. By Le Chatelier's principle, raising temperature favours the reverse process, namely escape of gas from solution. Therefore gas solubility decreases with increase in temperature.

Answer:

Dissolution of gases in liquids is generally exothermic, so higher temperature lowers solubility.

Q.1.12State Henry’s law and mention some important applications.v
Solution

Henry's law may be written as p = KH x, where p is partial pressure of the gas and x is its mole fraction in solution. Applications include carbonation of soft drinks under high CO2 pressure, controlling oxygen solubility in aquatic systems, explaining scuba-diving problems such as bends, and using helium-oxygen mixtures for deep-sea diving to reduce nitrogen absorption.

Answer:

Henry's law states that the solubility of a gas in a liquid is directly proportional to its partial pressure over the solution at a given temperature.

Q.1.13The partial pressure of ethane over a solution containing 6.56 x 10^-3 g of ethane is 1 bar. If the solution contains 5.00 x 10^-2 g of ethane, then what shall be the partial pressure of the gas?v
Solution

At constant temperature, Henry's law gives p proportional to amount dissolved for the same solvent. Therefore p2/p1 = mass2/mass1 = (5.00 x 10^-2)/(6.56 x 10^-3). Thus p2 = 1 x 7.62 = 7.62 bar.

Answer:

7.62 bar.

Q.1.14According to Raoult’s law, what is the relative lowering of vapour pressure of a dilute solution containing non-volatile solute equal to?v
Solution

For a dilute solution with non-volatile solute, Raoult's law gives (p1° - p1)/p1° = x2, where x2 is the mole fraction of solute.

Answer:

It is equal to the mole fraction of the solute.

Q.1.15The vapour pressure of pure liquids A and B are 450 and 700 mm Hg respectively, at 350 K. Find out the composition of the liquid mixture if total vapour pressure is 600 mm Hg. Also find the composition of the vapour phase.v
Solution

For an ideal solution, ptotal = xA pA° + xB pB° = xA(450) + (1 - xA)(700). Since ptotal = 600, xA = 0.40 and xB = 0.60. Partial pressures are pA = 0.40 x 450 = 180 mm Hg and pB = 0.60 x 700 = 420 mm Hg. Vapour mole fractions are yA = 180/600 = 0.30 and yB = 420/600 = 0.70.

Answer:

Liquid phase: xA = 0.40, xB = 0.60. Vapour phase: yA = 0.30, yB = 0.70.

Q.1.16Heptane and octane form 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 g of octane?v
Solution

Moles heptane = 26.0/100.2 = 0.259 mol and moles octane = 35.0/114.2 = 0.306 mol. Mole fraction heptane = 0.259/(0.259 + 0.306) = 0.459; octane = 0.541. Total vapour pressure = 0.459(105.2) + 0.541(46.8) = 73.6 kPa.

Answer:

73.6 kPa.

Q.1.17The 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.v
Solution

A 1 molal aqueous solution contains 1 mol solute in 1 kg water. Moles water = 1000/18 = 55.5 mol. Mole fraction of water = 55.5/(55.5 + 1) = 0.9823. Vapour pressure = xwater p° = 0.9823 x 12.3 = 12.08 kPa.

Answer:

12.08 kPa.

Q.1.18Calculate the mass of a non-volatile solute (molar mass 40 g mol^-1) which should be dissolved in 114 g octane to reduce its vapour pressure to 80%.v
Solution

If vapour pressure is reduced to 80% of pure octane, xoctane = 0.80 and xsolute = 0.20. Moles octane = 114/114 = 1.00 mol. Let moles solute be n. Then 1/(1 + n) = 0.80, so n = 0.25 mol. Mass solute = 0.25 x 40 = 10.0 g.

Answer:

10.0 g approximately.

Q.1.19A solution containing 30 g of non-volatile solute exactly in 90 g water has a vapour pressure of 2.8 kPa at 298 K. Further, 18 g of water is then added to the solution, the new vapour pressure becomes 2.9 kPa at 298 K. Calculate the molar mass of the solute.v
Solution

Let moles of solute be n. Initially moles water = 90/18 = 5. After adding water, moles water = 108/18 = 6. Since p = xwater p°, the same p° applies: 2.8(n + 5)/5 = 2.9(n + 6)/6. Solving gives n = 30/23 mol. Molar mass = 30/n = 23 g mol^-1.

Answer:

23 g mol^-1.

Q.1.20A 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.v
Solution

For equal mass percentages in water, freezing-point depression is proportional to moles of solute and therefore inversely proportional to molar mass. Cane sugar has molar mass 342 g mol^-1 and glucose has molar mass 180 g mol^-1. For cane sugar, ΔTf = 273.15 - 271 = 2.15 K. Hence ΔTf(glucose) = 2.15 x 342/180 = 4.09 K. Freezing point of glucose solution = 273.15 - 4.09 = 269.06 K.

Answer:

269.06 K.

Q.1.21Two elements A and B form compounds having formula AB2 and AB4. When dissolved in 20 g of benzene, 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 molal depression constant for benzene is 5.1 K kg mol^-1. Calculate atomic masses of A and B.v
Solution

The formula masses follow AB2 → A + 2B and AB4 → A + 4B. For AB2, molar mass = Kf w x 1000/(ΔTf W) = 5.1 x 1 x 1000/(2.3 x 20) = 110.9 g mol^-1. For AB4, molar mass = 5.1 x 1 x 1000/(1.3 x 20) = 196.2 g mol^-1. Let atomic masses be A and B. A + 2B = 110.9 and A + 4B = 196.2. Hence 2B = 85.3, B = 42.6 and A = 25.6.

Answer:

Atomic mass of A = 25.6 u and B = 42.6 u.

Q.1.22At 300 K, 36 g of glucose present in a litre of its solution has an osmotic pressure of 4.98 bar. If the osmotic pressure of the solution is 1.52 bars at the same temperature, what would be its concentration?v
Solution

For dilute solutions at the same temperature, π = CRT. Therefore C = π/(RT) = 1.52/(0.08314 x 300) = 0.0609 mol L^-1. The given glucose data also confirms RT because 36 g glucose = 0.20 mol L^-1 and 4.98/0.20 ≈ 24.9.

Answer:

0.061 mol L^-1.

Q.1.23Suggest the most important type of intermolecular attractive interaction in the following pairs. (i) n-hexane and n-octane (ii) I2 and CCl4 (iii) NaClO4 and water (iv) methanol and acetone (v) acetonitrile (CH3CN) and acetone (C3H6O).v
Solution

Non-polar molecules such as hydrocarbons and I2/CCl4 interact mainly through dispersion forces. Ionic sodium perchlorate interacts with polar water through ion-dipole forces. Methanol can donate hydrogen bonds to acetone oxygen. Acetonitrile and acetone are polar molecules, so dipole-dipole interactions dominate.

Answer:

(i) London dispersion; (ii) London dispersion; (iii) ion-dipole; (iv) hydrogen bonding/dipole-dipole; (v) dipole-dipole.

Q.1.24Based on solute-solvent interactions, arrange the following in order of increasing solubility in n-octane and explain. Cyclohexane, KCl, CH3OH, CH3CN.v
Solution

n-Octane is non-polar, so non-polar solutes dissolve best. KCl is ionic and least soluble. Methanol is strongly polar and hydrogen-bonded, so it is poorly soluble in octane. Acetonitrile is polar but less hydrogen-bonded than methanol. Cyclohexane is non-polar like n-octane and is most soluble.

Answer:

KCl < CH3OH < CH3CN < cyclohexane.

Q.1.25Amongst 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.v
Solution

Water dissolves compounds that can form strong hydrogen bonds or ion-like polar interactions. Formic acid and ethylene glycol are highly soluble because they form extensive hydrogen bonding. Phenol and pentanol have polar -OH groups but also sizeable hydrophobic parts, so they are only partially soluble. Toluene and chloroform are largely non-polar and are treated as insoluble in water.

Answer:

Highly soluble: formic acid and ethylene glycol. Partially soluble: phenol and pentanol. Insoluble: toluene and chloroform.

Q.1.26If the density of some lake water is 1.25 g mL^-1 and contains 92 g of Na+ ions per kg of water, calculate the molality of Na+ ions in the lake.v
Solution

Molality depends on moles of solute per kg solvent. Moles of Na+ = 92/23 = 4.0 mol in 1 kg water. Therefore molality = 4.0 m. The density is not required for molality.

Answer:

4.0 mol kg^-1.

Q.1.27If the solubility product of CuS is 6 x 10^-16, calculate the maximum molarity of CuS in aqueous solution.v
Solution

For CuS(s) ⇌ Cu2+ + S2-, if molar solubility is S, Ksp = [Cu2+][S2-] = S^2. Thus S = sqrt(6 x 10^-16) = 2.45 x 10^-8 M.

Answer:

2.45 x 10^-8 M.

Q.1.28Calculate the mass percentage of aspirin (C9H8O4) in acetonitrile (CH3CN) when 6.5 g of C9H8O4 is dissolved in 450 g of CH3CN.v
Solution

Mass percentage = mass of aspirin x 100/total mass of solution = 6.5 x 100/(6.5 + 450) = 1.42%.

Answer:

1.42% by mass.

Q.1.29Nalorphene (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.v
Solution

Molar mass of nalorphene = 311 g mol^-1. Moles in 1.5 mg = 1.5 x 10^-3/311 = 4.82 x 10^-6 mol. A 1.5 x 10^-3 m solution contains 1.5 x 10^-3 mol per kg water. Mass of water needed = (4.82 x 10^-6)/(1.5 x 10^-3) = 3.21 x 10^-3 kg = 3.21 g. The solute mass is tiny, so solution mass is about 3.21 g.

Answer:

About 3.21 g of solution.

Q.1.30Calculate the amount of benzoic acid (C6H5COOH) required for preparing 250 mL of 0.15 M solution in methanol.v
Solution

Moles required = M x V = 0.15 x 0.250 = 0.0375 mol. Molar mass of benzoic acid = 122 g mol^-1. Mass = 0.0375 x 122 = 4.58 g.

Answer:

4.58 g.

Q.1.31The 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.v
Solution

Freezing-point depression is a colligative property and depends on the number of solute particles. Electron-withdrawing groups increase acid strength. Trifluoroacetic acid is strongest, then trichloroacetic acid, while acetic acid is weakest. Stronger acid dissociation gives a larger van't Hoff factor and hence a greater depression in freezing point.

Answer:

The acids dissociate to different extents; stronger acids produce more ions and larger depression in freezing point.

Q.1.32Calculate the depression in freezing point of water when 10 g of CH3CH2CHClCOOH is added to 250 g of water. Ka = 1.4 x 10^-3, Kf = 1.86 K kg mol^-1.v
Solution

For the weak acid dissociation, HA ⇌ H+ + A-. Molar mass of CH3CH2CHClCOOH = 122.5 g mol^-1. Molality = (10/122.5)/0.250 = 0.326 m. Ka = Cα^2/(1 - α) with C ≈ 0.326, giving α = 0.0634. Thus i = 1 + α = 1.063. Depression = iKf m = (1.063)(1.86)(0.326) = 0.646 K.

Answer:

0.646 K.

Q.1.3319.5 g of CH2FCOOH is dissolved in 500 g of water. The depression in freezing point of water observed is 1.0 °C. Calculate the van’t Hoff factor and dissociation constant of fluoroacetic acid.v
Solution

Molar mass of CH2FCOOH = 78 g mol^-1. Moles = 19.5/78 = 0.250 mol; molality = 0.250/0.500 = 0.500 m. For water, ΔTf = iKf m, so i = 1.0/(1.86 x 0.500) = 1.08. For dissociation HA ⇌ H+ + A-, i = 1 + α, so α = 0.076. Ka = Cα^2/(1 - α) ≈ (0.500)(0.076)^2/(0.924) = 3.1 x 10^-3.

Answer:

i = 1.08; Ka = 3.1 x 10^-3 approximately.

Q.1.34Vapour 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.v
Solution

Moles glucose = 25/180 = 0.139 mol. Moles water = 450/18 = 25.0 mol. Mole fraction of water = 25.0/(25.0 + 0.139) = 0.9945. Vapour pressure = 0.9945 x 17.535 = 17.44 mm Hg.

Answer:

17.44 mm Hg.

Q.1.35Henry’s law constant for oxygen dissolved in water is 4.34 x 10^4 bar at 298 K. If the partial pressure of oxygen in air is 0.4 bar, calculate the concentration (in mol L^-1) of dissolved oxygen in water in equilibrium with air at 298 K.v
Solution

Henry's law gives mole fraction of oxygen, xO2 = p/KH = 0.4/(4.34 x 10^4) = 9.22 x 10^-6. One litre of water contains about 55.5 mol H2O, so dissolved oxygen concentration ≈ xO2 x 55.5 = 5.1 x 10^-4 mol L^-1.

Answer:

5.1 x 10^-4 mol L^-1.

Q.1.36100 g of liquid A (molar mass 140 g mol^-1) was dissolved in 1000 g of liquid B (molar mass 180 g 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.v
Solution

Moles A = 100/140 = 0.714; moles B = 1000/180 = 5.556. Hence xA = 0.1139 and xB = 0.8861. Partial pressure of B = xB pB° = 0.8861 x 500 = 443.0 torr. Therefore pA in solution = 475 - 443.0 = 32.0 torr. Since pA = xA pA°, pA° = 32.0/0.1139 = 280.6 torr.

Answer:

pA° = 280.6 torr; pA = 32.0 torr.

Q.1.38Benzene 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 80 g of benzene is mixed with 100 g of toluene.v
Solution

Moles benzene = 80/78.11 = 1.024; moles toluene = 100/92.14 = 1.085. xbenzene = 1.024/(1.024 + 1.085) = 0.486. Partial pressures: pbenzene = 0.486 x 50.71 = 24.62 mm Hg; ptoluene = 0.514 x 32.06 = 16.49 mm Hg. Therefore ybenzene = 24.62/(24.62 + 16.49) = 0.599.

Answer:

Mole fraction of benzene in vapour phase = 0.599.

Q.1.39The air is a mixture of gases at 298 K and total pressure 1 atm. Assuming the gases are nitrogen, oxygen and argon present in the ratio 78:21:1, calculate the partial pressure of these gases.v
Solution

Partial pressure equals mole fraction times total pressure. The ratio 78:21:1 gives mole fractions 0.78, 0.21 and 0.01. At total pressure 1 atm, the partial pressures are therefore 0.78 atm, 0.21 atm and 0.01 atm.

Answer:

pN2 = 0.78 atm, pO2 = 0.21 atm and pAr = 0.01 atm.

Q.1.40Determine 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.v
Solution

Use πV = inRT. Moles CaCl2 = πV/(iRT) = (0.75 x 2.5)/(2.47 x 0.0821 x 300) = 0.0308 mol. Molar mass CaCl2 = 111 g mol^-1, so mass = 0.0308 x 111 = 3.42 g.

Answer:

3.42 g CaCl2.

Q.1.41Determine 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.v
Solution

K2SO4 → 2K+ + SO4^2-, so complete dissociation gives i = 3. Moles K2SO4 = 0.025/174.3 = 1.43 x 10^-4 mol. Volume = 2 L, T = 298 K. π = i nRT/V = 3(1.43 x 10^-4)(0.0821)(298)/2 = 5.26 x 10^-3 atm.

Answer:

5.26 x 10^-3 atm.