Q. 1. What weight of AgCl will be precipitated when a solution containing 4.77 g of NaCl is added to a solution of 5.77 g of AgNO3?
(1978)
Ans. Sol. TIPS/Formulae : Write the balance chemical equation and use mole concept for limiting reagent.
From the given data, we find AgNO3 is limiting reagent as NaCl is in excess.
∵ 170.0 g of AgNO3 precipitates AgCl = 143.5 g
∴ 5.77 g of AgNO3 precipitates AgCl
= 4.87 g
Q. 2. One gram of an alloy of aluminium and magnesium when treated with excess of dil. HCl forms magnesium chloride, aluminium chloride and hydrogen. The evolved hydrogen, collected over mercury at 0°C has a volume of 1.20 litres at 0.92 atm. pressure. Calculate the composition of the alloy. [H = 1, Mg = 24, Al = 27] (1978)
Ans. Sol. TIPS/Formulae : (i) Find volume of H2 at N.T.P. (ii) Total amount of H2 liberated = H2 liberated by Mg & HCl + H2 liberated by Al & HCl.
Conversion of volume of H2 to N.T.P
Given conditions N.T.P conditions
P1 = 0.92 atm. P2 = 1 atm.
V1 = 1.20 litres V2 = ?
T1 = 0 + 273 = 273 K T2 = 273 K
Applying ideal gas equation,
= 1.104 litres = 1104 ml
The relevant chemical equations are
(i)
= 54 g = 67200 ml at NTP
(ii)
Wt. of alloy = 1 g Let the wt. of aluminium in alloy = x g
∴ Wt. of magnesium in alloy = (1 – x) g According to equation
(i) 54 g of Al = 67200 ml of H2 at N.T.P ∴ x g of Al = 6 = 1244.4 x ml of H2 at N.T.P
Similarly, from equation
(ii) 24 g of Mg = 22400 ml of H2 at N.T.P (1 – x) g of Mg = × (1 – x) = 933.3 (1 – x) ml of H2
Hence total vol. of H2 collected at N.T.P = 1244.4 x + 933.3 (1 – x) ml
But total vol. of H2 as calculated above = 1104 ml
∴ 1244.4 x + 933.3 (1 – x) = 1104 ml
1244.4 x – 933.3 x = 1104 – 933.3
311.1 x = 170.7, x = 0.5487
Hence 1 g of alloy contains Al = 0.5487 g
∴ Percentage of Al in alloy == 54.87%
% of Mg in alloy = 100 – 54.87 = 45.13%
Q. 3. Igniting MnO2 converts it quantitatively to Mn3O4. A sample of pyrolusite is of the following composition : MnO2 80%, SiO2 and other inert constituents 15%, rest being water. The sample is ignited in air to constant weight. What is the percentage of Mn in the ignited sample? (1978) [O = 16, Mn = 54.9]
Ans. Sol.
Let the amount of pyrolusite ignited = 100.00 g
∴ Wt. of MnO2 = 80 g (80% of 100 g = 80 g) Wt. of SiO2 and other inert substances = 15 g Wt. of water = 100 – (80 + 15) = 5 g
According to equation, 260.7 g of MnO2 gives = 228.7 g of Mn3O4
∴ 80 g of MnO2 gives = × 80 = 70.2 g of Mn3O4
NOTE :
During ignition, H2O present in pyrolusite is removed while silica and other inert substances remain as such.
∴ Total wt. of the residue = 70.2 + 15 = 85.2 g
Calculation of % of Mn in ignited Mn3O4
3 Mn = Mn3O4
3 × 54.9 = 164.7 g 3 × 54.9 + 64 = 228.7g
Since, 228.7 g of Mn3O4 contains 164.7 g of Mn
70.2 g of Mn3O4 contains = × 70.2 = 50.55 g of Mn
Weight of residue = 85.2 g
Hence, percentage of Mn is the ignited sample
x 100 = 59.33%
Q. 4. 4.215 g of a metallic carbonate was heated in a hard glass tube and the CO2 evolved was found to measure 1336 ml at 27°C and 700 mm pressure. What is the equivalent weight of the metal? (1979)
Ans. Sol. TIPS/Formulae : (i) Find the volume of CO2 at NTP
(ii) Find molecular wt. of metal carbonate
(iii) Find the wt. of metal
(iv) Calculate equivalent weight of metal
Given P1 = 700 mm, P2 = 760 mm, V1 = 1336 ml, V2 = ?
T1 = 300 K, T2 = 273 K
= 1119.78 ml = 1.12 L at NTP
∴ 1.12 L of CO2 is given by carbonate = 4.215 g
Molecular weight of metal carbonate =
= 84.3
Metal carbonate is MCO3 = M + 12 + 48 = M + 60
Atomic weight of M = 84.3 – 60 = 24.3
Eq. wt. of metal = × M. wt. x 24.3 = 12.15
Q. 5. (a) 5.5 g of a mixture of FeSO4. 7H2O and Fe2(SO4)3. 9H2O requires 5.4 ml of 0.1 N KMnO4 solution for complete oxidation. Calculate the number of gram mole of hydrated ferric sulphate in the mixture.
(b) The vapour density (hydrogen = 1) of a mixture consisting of NO2 and N2O4 is 38.3 at 26.7°C. Calculate the number of moles of NO2 in 100 g of the mixture. (1979)
Ans. Sol. (a) Equivalents of KMnO4 = Equivalents of FeSO4 . 7H2O
5.4 ml 0.1 N KMnO4 == 5.4 × 10–4 equivalentsAmount of FeSO4 = 5.4 × 10–4 × Mol wt. of FeSO4.7H2O
= 5.4 × 10–4 × 278 = 0.150 g
Total weight of mixture = 5.5 g
Amount of ferric sulphate = 5.5 – 0.150 g = 5.35 g
Hence Moles of ferric sulphate =
= 9.5 × 10–3 gram-mole
(b) Using the relation, Mol. wt. = 2 × vapour density, we get Mol. wt. = 2 × 38.3 = 76.6
No. of moles = = 1.30 ....(i)
Let weight of NO2 in mixture = x g
Then weight of N2O4 in mixture = 100 – x No. of moles of NO2 = ....(ii)
No. of moles of N2O4 = ...(iii)
- According to problem
On solving the equation we find, x = 20.1
∴ weight of NO2 = 20.1 g Moles of NO2 = = 0.437 moles.
Q. 6. 5 ml of a gas containing only carbon and hydrogen were mixed with an excess of oxygen (30 ml) and the mixture exploded by means of an electric spark. After the explosion, the volume of the mixed gases remaining was 25 ml. On adding a concentrated solution of potassium hydroxide, the volume further diminished to 15 ml of the residual gas being pure oxygen. All volumes have been reduced to N.T.P.
Calculate the molecular formula of the hydrocarbon gas. (1979)
Ans. Sol. Volume of oxygen taken = 30 ml, Volume of unused oxygen = 15 ml
Volume of O2 used = Volume of O2 added – Volume of O2 left
= 30 – 15 = 15 ml
Volume of CO2 produced = Volume of gaseous mixture after explosion – Volume of unused oxygen or Volume of CO2 produced = 25 – 15 = 10 ml
Volume of hydrocarbon = 5 ml General equation for combustion of a hydrocarbon is as follows -
∴ Volume of CO2 produced = 5x, Since Volume of CO2 = 10 ml
∴ 5x = 10 ⇒ x = 2, Volume of O2 used = 15 ml
⇒ 2 + = 3 (∵ x = 2) ⇒ 8 + y = 12 ∴ y = 4
Hence Molecular formula of hydrocarbon is C2H4.
Q. 7. In the analysis of 0.500 g sample of feldspar, a mixture of chlorides of sodium and potassium is obtained which weighs 0.1180g. Subsequent treatment of mixed chlorides with silver nitrate gives 0.2451g of silver chloride. What is the percentage of sodium oxide and potassium oxide in feldspar.
(1979)
Ans. Sol. TIPS/Formulae : (i) Equate given mass of AgCl against mass obtained from NaCl and KCl
(ii) 2NaCl ≡ Na2O & 2KCl ≡ K2O Let amount of NaCl in mixture = x gm
∴ amount of KCl in mixture = (0.118 - x) gm
NaCl + AgNO3 —→ AgCl + NaNO3 58.5 g
143.5 g
∵ 58.5 g NaCl gives AgCl = 143.5g
∴ x g NaCl gives AgCl = × x g
Again
KCl + AgNO3 —→ AgCl + KNO3
74.5 g 143.5 g
∵ 74.5 g KCl gives AgCl = 143.5g
∴ (0.118 – x) g KCl gives AgCl =
Total weight of AgCl = 0.2451g
= 0.2451
∴ x = 0.0338g
∴ Amount of NaCl in mixture = 0.0338g
∴ Amount of KCl in mixture = 0.118 – 0.0338 = 0.0842g
Since
2NaCl ≡ Na2O
2 × 58.5 62
= 117.0
∵ 117g NaCl is equivalent to = 62.0g Na2O
∴ 0.0338g NaCl is equivalent to = × 0.0338 g Na2O
= 0.0179g
% of Na2O in 0.5g of feldspar = × 100 = 3.58%
2KCl ≡ K2O
2 × 74.5 = 149 94
∵ 149g of KCl is equivalent to = 94g K2O
∴ 0.0842g of KCl is equivalent to = = 0.0531g K2O
∴ % of K2O in 0.5g of feldspar = × 100 = 10.62%
% of Na2O in feldspar = 3.58%
% of K2O in feldspar = 10.62%
Q. 8. A compound contains 28 percent of nitrogen and 72 percent of metal by weight. 3 atoms of metal combine with 2 atoms of N. Find the atomic weight of metal. (1980)
Ans. Sol. According to problem, three atoms of M combine with 2 atoms of N
∴ Formula of compound is M3N2 (Where M is the metal) Equivalent wt of N = (∵ valency of N in compound is 3)
∵ 28 g N combines with = 72g metal
∴ 14/3 N combines with = = 12
∴ Eq. wt. of metal = 12
At wt of metal = Eq. wt × valency = 12 × 2 = 24 [Valency of metal = 2]
Q. 9. (i) A sample of MnSO4.4H2O is strongly heated in air. The residue is Mn3O4.
(ii) The residue is dissolved in 100 ml of 0.1 N FeSO4 containing dilute H2SO4.
(iii) The solution reacts completely with 50 ml of KMnO4 solution.
(iv) 25 ml of the KMnO4 solution used in step (iii) requires 30 ml of 0.1 N FeSO4 solution for complete reaction.
Find the amount of MnSO4.4H2O present in the sample. (1980)
Ans. Sol. Following reactions take place
Mn3O4 + 2FeSO4 + 4H2SO4 —→ Fe2(SO4)3 + 3MnSO4 + 4H2O
Milliequivalents of FeSO4 in 30 ml of 0.1N FeSO4 = 30 × 0.1 = 3 m. eq.
According to problem step (iv) 25 ml of KMnO4 reacts with = 3 m eq of FeSO4
Thus in step (iii) of the problem, 50 ml of KMnO4 reacts with = x m.eq. of FeSO4
= 6 meq of FeSO4
Milli eq. of 100 ml of 0.1N FeSO4 = 100 × 0.1 = 10 m eq.
FeSO4 which reacted with Mn3O4 = (10–6) = 4 m eq.
Milli eq of FeSO4 = Milli eq. of Mn3O4 (∵ Milli eq of oxidising agent and reducing agent are equal)
∵ Mn3O4 ≡ 3MnSO4 .4H2O
∴ 1 Meq of Mn3O4 = 3 Meq of MnSO4 . 4H2O
∴ 4 Meq of Mn3O4 = 12 Meq of MnSO4 . 4H2O
Eq. wt of MnSO4.4H2O == 111.5
Wt of MnSO4.4H2O in sample = 12 × 111.5 = 1338 mg = 1.338g.
Q. 10. (a) One litre of a sample of hard water contains 1 mg of CaCl2 and 1 mg of MgCl2. Find the total hardness in terms of parts of CaCO3 per 106 parts of water by weight.
(b) A sample of hard water contains 20 mg of Ca++ ions per litre. How many milli-equivalent of Na2CO3 would be required to soften 1 litre of the sample?
(c) 1 gm of Mg is burnt in a closed vessel which contains 0.5 gm of O2.
(i) Which reactant is left in excess?
(ii) Find the weight of the excess reactants?
(iii) How may milliliters of 0.5 N H2SO4 will dissolve the residue in the vessel. (1980)
Ans. Sol. (a)
From this it is evident, that 111 mg CaCl2 will give CaCO3 = 100mg
∴ 1 mg CaCl2 will give CaCO3 = mg = 0.90 mg
95 mg MgCl2 gives CaCO3 = 100 mg
∴ 1 mg MgCl2 gives CaCO3 = mg = 1.05 mg
∴ Total CaCO3 formed by 1 mg CaCl2 and 1 mg MgCl2 = 0.90 + 1.05 = 1.95 mg
∴ Amount of CaCO3 present per litre of water = 1.95mg
∴ wt of 1 ml of water = 1g = 103 mg
∴ wt of 1000 ml of water = 103 × 103 = 106mg
∴ Total hardness of water in terms of parts of CaCO3 per 106 parts of water by weight = 1.95 parts.
(b) Eq wt of Ca++ == 20
Ca2+ + Na2CO3 —→ CaCO3 + 2Na +
1 milliequivalent of Ca2+ = 20 mg
1 milliequivalent of Na2CO3 is required to soften 1 litre of hard water.
(c)
∵ 32g of O2 reacts with = 48g Mg
∴ 0.5g of O2 reacts with = x 0.5 = 0.75g
Weight of unreacted Mg = 1.00 – 0.75 = 0.25g
Thus Mg is left in excess.
Weight of MgO formed = x 0.75 = 1.25g
MgO + H2SO4 —→ MgSO4 + H2O
(40g) According to reaction
∵ 40g MgO is dissolved it gives 1000 ml of 1 N. H2SO4
∴ 40 g MgO is dissolved it gives 2000 ml 0.5 N H2SO4
∴ 1.25 MgO is dissolved it gives
ml of 0.5 N H2SO4
= 62.5ml of 0.5N H2SO4
Q. 11. A hydrocarbon contains 10.5g of carbon per gram of hydrogen. 1 litre of the vapour of the hydrocarbon at 127°C and 1 atmosphere pressure weighs 2.8g. Find the molecular formula. (1980)
Ans. Sol.
Given P = 1 atm V = 1L, T = 127°C = 127 + 273 = 400 K
PV = nRT (Ideal gas equation)
= 0.0304
Mol. wt == 92.10
∴ Emperical formula = C7H8
Emperical formula, wt = 12 × 7 + 1 × 8 = 92
Molecular formula = n × empirical formula
= 1(C7H8) = C7H8
Q. 12. Find (1980) (i) The total number of neutrons and (ii) The total mass of neutron in 7 mg of 14C. (Assume that mass of neutron = mass of hydrogen atom)
Ans. Sol.
(i) No. of C atoms in 14g of 14C = 6.02 × 1023
∴ No. of C atom in 7 mg (7/1000g) of 14C
= 3.01 × 1020
No. of neutrons in 1 carbon atom = 7
∴ Total no. of neutrons in 7 mg of 14C = 3.01× 1020 ×7
= 21.07 × 1020
Wt of 1 neutron = wt of 1 hydrogen atom
∴ Wt of 3.01 × 1020 × 7 neutrons
= 3.5 × 10–3g
Q. 13. A mixture contains NaCl and unknown chloride MCl.
(i) 1 g of this is dissolved in water. Excess of acidified AgNO3 solution is added to it. 2.567 g of white ppt. is formed.
(ii) 1 g of original mixture is heated to 300°C. Some vapours come out which are absorbed in acidified AgNO3 solution, 1.341 g of white precipitate was obtained.
Find the molecular weight of unknown chloride. (1980)
Ans. Sol. Weight of AgCl formed = 2.567 g
Amount of AgCl formed due to MCl = 1.341 g (∵ NaCl does not decompose on heating to 300°C)
∴ Weight of AgCl formed due to NaCl = 2.567 – 1.341= 1.226g
∵ 143.5g of AgCl is obtained from NaCl = 58.5g
∴ 1.226 g of AgCl is obtained from NaCl
x 1.226 = 0.4997 g
∴ Wt of MCl in 1 g of mixture = 1.000 – 0.4997 = 0.5003g
∵ 1.341 g of AgCl is obtained from MCl = 0.5003g
∴ 143.5g of AgCl is obtained from MCl
x 143.5 = 53.53 g
∴ Molecular weight of MCl = 53.53
Q. 14. A 1.00 gm sample of H2O2 solution containing X per cent H2O2 by weight requires X ml of a KMnO4 solution for complete oxidation under acidic conditions. Calculate the normality of the KMnO4 solution. (1981 - 3 Marks)
Ans. Sol. The complete oxidation under acidic conditions can be represented as follows:
5H2O2 + 2MnO4- + 6H+ → 5O2 + 2Mn2++ 8H2O
Since 34 g of H2O2 = 2000 ml of 1N . H2O2
∴ 34 g of H2O2 = 2000 ml of 1N KMnO4 [∵ N1V1 = N 2V2]
orH2O2 = of 1N KMnO4
Therefore the unknown normality =
or 0.588 N
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