Chapter 1 Basic Concepts of Chemistry: Q&A

In this post, you will get the Some basic concepts of chemistry NCERT solutions in addition to other question answer as well.

1. Calculate the molecular mass of the following: (i) H₂O (ii) CO₂ (iii) CH₄

Answer: (i) H₂O:
The molecular mass of water = (2 x Atomic mass of hydrogen) + (1 x Atomic mass of oxygen)
= [2(1.0084) + 1(16.00 u)] = 2.016 u + 16.00 u = 18.016 = 18.02 u
(ii) CO₂:
The molecular mass of carbon dioxide = (1 x Atomic mass of carbon) + (2 x Atomic mass of oxygen)
= [1(12.011 u) + 2 (16.00 u)] = 12.011 u + 32.00 u = 44.01 u
(iii) CH₄:
The molecular mass of methane = (1 x Atomic mass of carbon) + (4 x Atomic mass of hydrogen)
= [1(12.011 u) + 4 (1.008 u)] = 12.011 u + 4.032 u = 16.043 u

2. Calculate the mass percent of different elements present in sodium sulphate.

Answer: The molecular formula of sodium sulphate is Na₂SO₄.

Molar mass of Na₂SO₄ = [(2 × 23.0) + (32.066) + 4 (16.00)] = 142.066 g

Mass percent of an element = [^{Mass of that element in the compound}/_{Molar mass of the compound}] * 100

Now, mass percentage of sodium = [^{46.0 g}/_{142.066 g}]*100 = 32.379 % = 32.4 %

Mass percentage of sulphur = [^{32.066 g}/_{142.066 g}]*100 = 22.57 % = 22.6 %

Mass percentage of oxygen = [^{64.0 g}/_{142.066 g}]*100 = 45.049 % = 45.05 %

3. Determine the empirical formula of an oxide of iron which has 69.9% iron and 30.1% dioxygen by mass.

Answer: % of iron by mass = 69.9 % [Given]
% of oxygen by mass = 30.1 % [Given]

Relative moles of iron in iron oxide = ^{% Iron by mass}/_{Atomic mass of iron} = ^69.9/_55.85 = 1.25

Relative moles of oxygen in iron oxide = ^{% Oxygen by mass}/_{Atomic mass of oxygen} = ^30.1/₁₆ = 1.88

Now, the simplest molar ratio, Fe : O = 1.25 : 1.88 = 1 : 1.5 = 2 : 3

So, the empirical formula of iron oxide is Fe₂O₃.

4. Calculate the amount of carbon dioxide that could be produced when
(i) 1 mole of carbon is burnt in air.
(ii) 1 mole of carbon is burnt in 16 g of dioxygen.
(iii) 2 moles of carbon are burnt in 16 g of dioxygen.

Answer: The balanced reaction of combustion of carbon can be written as:

C + O₂ → CO₂

(i) As per the balanced equation, 1 mole of carbon burns in1 mole of dioxygen (air) to produce 1 mole of carbon dioxide.
(ii) According to the question, only 16 g of dioxygen is available. Hence, it will react with 0.5 mole of carbon to give 22 g of carbon dioxide. Hence, it is a limiting reactant.
(iii) According to the question, only 16 g of dioxygen is available. It is a limiting reactant. Thus, 16 g of dioxygen can
combine with only 0.5 mole of carbon to give 22 g of carbon dioxide.

5. Calculate the mass of sodium acetate (CH3COONa) required to make 500 mL of 0.375 molar aqueous solution. Molar mass of sodium acetate is 82.0245 g mol^-1.

Answer: 0.375 M aqueous solution of sodium acetate indicates that 1000 mL of solution contains 0.375 moles of sodium acetate.
So, Number of moles of sodium acetate in 500 mL = (^0.375/₁₀₀₀) * 500 = 0.1875 mol

Given that the molar mass of sodium acetate is 82.0245 g/mol.

Mass of sodium acetate = No. of moles * Molar mass = 0.1875 mol * 82.0245 g/mol = 15.38 g

6. Calculate the concentration of nitric acid in moles per litre in a sample which has a density, 1.41 g mL^-1 and
the mass per cent of nitric acid in it being 69%.

Answer: Mass percent of nitric acid in the sample = 69% [Given]
Thus, 100 g of nitric acid contains 69 g of nitric acid by mass.
Molar mass of nitric acid (HNO₃) = 63 g/mol
So, Number of moles in 69 g of HNO₃ = ^{Given mass}/_{Molar mass} = ^{69 g}/_{63 g/mol} = 1.095 mol

Volume of 100 g of nitric acid solution = ^{Mass of solution}/_{Density of solution} = ^{100 g}/_{1.41 g/ml} = 70.92 ml = 70.92 * 10^-3 L

Concentration of nitric acid = ^{Moles of nitric acid}/_{Volume of solution} = ^{1.095 mol}/_{70.92 * 10^-3 L} = 15.44 M

7. How much copper can be obtained from 100 g of copper sulphate (CuSO₄)?

Answer: 1 mole of CuSO₄ contains 1 mole of copper.
Molar mass of CuSO₄ = 159.5 g/mol
159.5 g of CuSO₄ contains 63.5 g of copper.

100 g of CuSO4 will contain of copper = 39.81 g

Hence, the amount of copper that can be obtained from 100 g CuSO₄ is 39.81 g.

8. Determine the molecular formula of an oxide of iron in which the mass per cent of iron and oxygen are 69.9 and 30.1 respectively. Given that the molar mass of the oxide is 159.69 g mol^-1.

Answer: Mass percent of iron (Fe) = 69.9%
Mass percent of oxygen (O) = 30.1%

Number of moles of iron in iron oxide = ^{% Iron by mass}/_{Atomic mass of iron} = ^69.9/_55.85 = 1.25

Number of moles of oxygen in iron oxide = ^{% Oxygen by mass}/_{Atomic mass of oxygen} = ^30.1/₁₆ = 1.88

Now, the simplest molar ratio, Fe : O = 1.25 : 1.88 = 1 : 1.5 = 2 : 3

So, the empirical formula of iron oxide is Fe₂O₃.

Empirical mass of Fe₂O₃ = 159.7 g/mol

Molar mass of Fe₂O₃ = 159.69 g/mol

So, n = ^{Molar mass}/_{Empirical mass} = ^159.69/_159.7 = 1

Molecular formula of a compound is obtained by multiplying the empirical formula with n.
Thus, the empirical formula of the given oxide is Fe₂O₃ and n is 1.
Hence, the molecular formula of the oxide is Fe₂O₃.

9. Calculate the atomic mass (average) of chlorine using the following data:

Isotope of chlorine	% natural abundance	Molar mass
Cl-35	75.77	34.9689
Cl-37	24.23	36.9659

Answer: The average atomic mass of chlorine is:

Hence, the average atomic mass of chlorine is 35.5 u.

10. In three moles of ethane (C₂H₆), calculate the following:
(i) Number of moles of carbon atoms.
(ii) Number of moles of hydrogen atoms.
(iii) Number of molecules of ethane.

Answer: (i) 1 mole of C₂H₆ contains 2 moles of carbon atoms.
Number of moles of carbon atoms in 3 moles of C₂H₆ = 2 × 3 = 6 moles.
(ii) 1 mole of C₂H₆ contains 6 moles of hydrogen atoms.
Number of moles of carbon atoms in 3 moles of C₂H₆ = 3 × 6 = 18 moles.
(iii) 1 mole of C₂H₆ contains 6.023 × 10²³ molecules of ethane.
Number of molecules in 3 moles of C₂H₆ = 3 × 6.023 × 10²³ = 18.069 × 10²³ molecules.

11. What is the concentration of sugar (C₁₂H₂₂O₁₁) in mol/L, if its 20 g are dissolved in enough water to make a final volume upto 2 L?

Answer: Mass of sugar = 20 g

Molar mass of sugar = (12*12)+(22*1)+(11*16) = 342 g/mol

Volume of solution = 2 L

Moles of sugar = ^{Mass of sugar}/_{Molar mass of sugar} = ^{20 g}/_{342 g/mol} = 0.0585 mol

Molarity = ^{Moles of sugar}/_{Volume of solution} = ^{0.0585 mol}/_{2 L} = 0.02925 mol/L

12. If the density of methanol is 0.793 kg/L, what is its volume needed for making 2.5 L of its 0.25 M solution?

Answer: Molar mass of methanol (CH₃OH) = (1×12)+(4×1)+(1×16) = 32 g/mol

Moles of methanol = Molarity * Volume(in L) = 0.25 M * 2.5 L = 0.625 mol

Mass of methanol = Moles * Molar mass = 0.625 mol * 32 g/mol = 20 g = 0.02 Kg

Volume required = ^Mass/_Density = ^0.02/_0.793 = 0.02522 L = 25.22 ml

13. Pressure is determined as force per unit area of the surface. The SI unit of pressure, Pascal is as shown
as: 1 Pa = 1 Nm^-2
If mass of air at sea level is 1034 gcm^-2, calculate the pressure in Pascal.

Answer : Pressure is defined as force acting per unit area of the surface.

P = 1.01332 × 10⁵ kgm^-1s^-2
We know,
1 Pa = 1 kgm^-1s^-2
So, Pressure = 1.01332 × 10⁵ Pa

14. What is the SI unit of mass? How is it defined?

Answer: The SI unit of mass is kilogram (kg). 1 Kilogram is defined as the mass equal to the mass of the international
prototype of kilogram.

15. Match the following prefixes with their multiples:

S No.	Prefixes	Multiples
(i)	micro	106
(ii)	deca	109
(iii)	mega	10-6
(iv)	giga	10-15
(v)	femto	10

Answer: The correct matches is as:

S No.	Prefixes	Multiples
(i)	micro	10-6
(ii)	deca	1010
(iii)	mega	106
(iv)	giga	109
(v)	femto	10-15

16. What do you mean by significant figures?

Answer: Significant figures are those meaningful digits that are known with certainty. They indicate uncertainty in an experiment or calculated value. For example, if 15.6 mL is the result of an experiment, then 15 is certain while 6 is uncertain, and the total number of significant figures are 3. Hence, significant figures are defined as the total number of digits in a number including the last digit that represents the uncertainty of the result.

17. A sample of drinking water was found to be severely contaminated with chloroform, CHCl₃, supposed to be
carcinogenic in nature. 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: (i) 1 ppm is equivalent to 1 part out of 1 million (10⁶) parts.
Mass percent of 15 ppm chloroform in water = ¹⁵/_10⁶ *100 = 1.5*10^-3 %

(ii) 100 g of the sample contains 1.5 × 10^-3g of CHCl₃.
So, 1000 g or 1 Kg of the sample contains 1.5 × 10^-2g of CHCl₃.

Molar mass of CHCl₃ = 119.5 g/mol

Mass of solvent (sample) = 1 Kg
Molality of chloroform in water = ^{1.5 × 10-2}/_119.5*1 = 1.25 * 10^-4 mol/Kg

18. Express the following in the scientific notation:
(i) 0.0048 (ii) 234,000 (iii) 8008 (iv) 500.0 (v) 6.0012

Answer: (i) 0.0048 = 4.8 x 10^-3
(ii) 234, 000 = 2.34 x 10⁵
(iii) 8008 = 8.008 x 10³
(iv) 500.0 = 5.000 x 10²
(v) 6.0012 = 6.0012

19. How many significant figures are present in the following?
(i) 0.0025 (ii) 208 (iii) 5005 (iv) 126,000 (v) 500.0 (vi) 2.0034

Answer: (i) There are 2 significant figures.
(ii) There are 3 significant figures.
(iii) There are 4 significant figures.
(iv) There are 3 significant figures.
(v) There are 4 significant figures.
(vi) There are 5 significant figures.

20. Round up the following upto three significant figures:
(i) 34.216 (ii) 10.4107 (iii) 0.04597 (iv) 2808

Answer: (i) 34.2 (ii) 10.4 (iii) 0.0460 (iv) 2810

21. The following data are obtained when dinitrogen and dioxygen react together to form different compounds:

S No.	Mass of dinitrogen	Mass of dioxygen
1.	14 g	16 g
2.	14 g	32 g
3.	28 g	32 g
4.	28 g	80 g

(a) Which law of chemical combination is obeyed by the above experimental data? Give its statement.
(b) Fill in the blanks in the following conversions:
(i) 1 km = …………………. mm = …………………. pm
(ii) 1 mg = …………………. kg = …………………. ng
(iii) 1 mL = …………………. L = …………………. dm3

Answer: (a) If we fix the mass of dinitrogen at 28 g, then the masses of dioxygen that will combine with the fixed mass of
dinitrogen are 32 g, 64 g, 32 g, and 80 g.
The masses of dioxygen bear a whole number ratio of 2:4:2:5.

Hence, the given experimental data obeys the law of multiple proportions.

The law states that if two elements combine to form more than one compound, then the masses of one element that combines with the fixed mass of another element are in the ratio of small whole numbers.

(b)

22. If the speed of light is 3.0 x 10⁸ ms^-1, calculate the distance covered by light in 2.00 ns.

Answer: Time taken to cover the distance = 2.00 ns = 2.00 x 10^-9 s
Speed of light = 3.0 x 10⁸ ms^-1
Distance travelled by light in 2.00 ns = Speed of light x Time taken = (3.0 x 10⁸ ms^-1)*(2.00 x 10^-9 s) = 0.600 m = 6.00 x 10^-1 m

23. In a reaction, A + B₂ → AB₂

Identify the limiting reagent, if any, in the following reaction mixtures:

(i) 300 atoms of A + 200 molecules of B

(ii) 2 mol A + 3 mol B

(iii) 100 atoms of A + 100 molecules of B

(iv) 5 mol A + 2.5 mol B

(v) 2.5 mol A + 5 mol B

Answer: A limiting reagent determines the extent of a reaction. It is the reactant which is the first to get consumed during a reaction, thereby causing the reaction to stop and limiting the amount of products formed.
(i) According to the given reaction, 1 atom of A reacts with 1 molecule of B. Thus, 200 molecules of B will react with 200 atoms of A, thereby leaving 100 atoms of A unused. Hence, B is the limiting reagent.

(ii) According to the reaction, 1 mol of A reacts with 1 mol of B. Thus, 2 mol of A will react with only 2 mol of B. As a result, 1 mol of B will not be consumed. Hence, A is the limiting reagent.

(iii) According to the given reaction, 1 atom of A combines with 1 molecule of B. Thus, all 100 atoms of A will combine with all 100 molecules of B. Hence, the mixture is stoichiometric where no limiting reagent is present.

(iv) 1 mol of atom A combines with 1 mol of molecule B. Thus, 2.5 mol of B will combine with only 2.5 mol of A. As a result, 2.5 mol of A will be left as such. Hence, B is the limiting reagent.

(v) According to the reaction, 1 mol of atom A combines with 1 mol of molecule B. Thus, 2.5 mol of A will combine with only 2.5 mol of B and the remaining 2.5 mol of B will be left as such. Hence, A is the limiting reagent.

24. Dinitrogen and dihydrogen react with each other to produce ammonia according to the following chemical equation:
N₂(g)+ H₂(g) → NH₃(g)
(i) Calculate the mass of ammonia produced if 2.00 x 10³g dinitrogen reacts with 1.00 x 10³g of dihydrogen.
(ii) Will any of the two reactants remain unreacted?
(iii) If yes, which one and what would be its mass?

Answer: Balancing the given chemical equation: N₂(g)+ 3H₂(g) → 2NH₃(g)

(i) From the equation, 1 mole (28 g) of dinitrogen reacts with 3 mole (6 g) of dihydrogen to give 2 mole (34 g) of ammonia.

2.00 × 10³ g of dinitrogen will react with dihydrogen = (^{6 g}/_{28 g}) * (2.00 × 10³ g) = 428.6 g
Given amount of dihydrogen is 1.00 × 10³ g, which is in excess as compared to dinitrogen.
Hence, N₂ is the limiting reagent.

From the reaction, 28 g of N₂ produces 34 g of NH₃

Mass of ammonia produced by 2000 g of N₂ = (^{34 g}/_{28 g})*(2000 g) = 2428.57 g

(ii) N₂ is the limiting reagent and H₂ is the excess reagent. Hence, H₂ will remain unreacted.
(iii) Mass of dihydrogen left unreacted = (1.00 × 10³ g) – (428.6 g) = 571.4 g

25. How are 0.50 mol Na₂CO₃ and 0.50 M Na₂CO₃ different?

Answer: Molar mass of Na₂CO₃ = (2 × 23) + 12.00 + (3× 16) = 106 g/mol
1 mole of Na₂CO₃ means 106 g of Na₂CO₃. So, 0.5 mol of Na₂CO₃ = 53 g Na₂CO₃

While 0.50 M of Na₂CO₃ = 0.50 mol/L Na₂CO₃. Hence, 0.50 M Na₂CO₃ means that 0.50 mol of Na₂CO₃ is present in 1 L of water or 53 g of Na₂CO₃ is present in 1 L of water.

26. If ten volumes of dihydrogen gas react with five volumes of dioxygen gas, how many volumes of water vapour would be produced?

Answer: Reaction of dihydrogen with dioxygen can be written as: 2H₂ + O₂ → 2H₂O

Now, two volumes of dihydrogen react with one volume of dihydrogen to produce two volumes of water vapour. Hence, ten volumes of dihydrogen will react with five volumes of dioxygen to produce ten volumes of water vapour.

27. Convert the following into basic units:
(i) 28.7 pm
(ii) 15.15 pm
(iii) 25365 mg

Answer: (i) 28.7 pm:
Since, 1 pm = 10^-12 m
So, 28.7 pm = 28.7 × 10^-12 m = 2.87 × 10^-11 m
(ii) 15.15 pm:
Since, 1 pm = 10^-12 m
So, 15.15 pm = 15.15 × 10^-12 m = 1.515 × 10^-11 m
(iii) 25365 mg:
Since, 1 mg = 10^-3 g
25365 mg = 2.5365 × 10⁴ × 10^-3 g = 2.5365 × 10¹ g
Also, 1 g = 10^-3 Kg
So, 2.5365 × 10¹ g = 2.5365 × 10¹ × 10^-3 kg = 2.5365 × 10^-2 Kg

28. Which one of the following will have largest number of atoms?
(i) 1 g Au (s)
(ii) 1 g Na (s)
(iii) 1 g Li (s)
(iv) 1 g of Cl₂(g)

Answer: N_A is Avogadro’s number whose value is 6.022 x 10²³ particles (atoms/molecules/ions).

(i) 1 g Au = 1/197 mol = N_A/197 atoms = 3.06 × 10²¹ atoms

(ii) 1 g Na = 1/23 mol = N_A/23 atoms = 26.2 × 10²¹ atoms

(iii) 1 g Li = 1/7 mol = N_A/7 atoms = 86.0 × 10²¹ atoms

(iv) 1 g Cl₂ = 1/71 mol = N_A/71 molecules = N_A/35.5 atoms = 16.96 × 10²¹ atoms

Hence, 1 g of Li (s) will have the largest number of atoms.

29. Calculate the molarity of a solution of ethanol in water in which the mole fraction of ethanol is 0.040. Assume
the density of water is to be 1 g/cm³.

Answer: Assuming that the volume of water is 1 L.

Since, the density of water is 1 g/cm³, so, mass of water = 1000 g

Molar mass of water = 18 g/mol

Number of moles of water = ^{Mass of water}/_{Molar mass of water} = ¹⁰⁰⁰/₁₈ = 55.55 mol

Molarity of ethanol solution = ^{Moles of ethanol}/_{Volume of solution} = ^{2.314 mol}/_{1 L} = 2.314 M

30. What will be the mass of one ¹²C atom in g?

Answer: 1 mole of carbon atoms = 6.023 × 10²³ atoms of carbon = 12 g of carbon

Mass of one ¹²C atom = ¹²/_{6.023 x 10²³} = 1.993 × 10^-23 g

31. How many significant figures should be present in the answer of the following calculations?

(i) (0.02856 x 298.15 x 0.112)/0.5785
(ii) 5 × 5.364
(iii) 0.0125 + 0.7864 + 0.0215

Answer: (i) Least precise number of calculation = 0.112
Number of significant figures in the answer = Number of significant figures in the least precise number = 3
(ii) Least precise number of calculation = 5.364
Number of significant figures in the answer = Number of significant figures in 5.364 = 4
(iii) Least number of decimal places in each term is four, the number of significant figures in the answer is also 4.

32. Use the data given in the following table to calculate the molar mass of naturally occurring argon isotopes:

Isotope	Molar mass (g/mol)	% Abundance
Ar-36	35.96755	0.337
Ar-38	37.96272	0.063
Ar-40	39.9624	99.600

Answer: The average molar mass of argon is:

Hence, the average molar mass of Argon is 40 gmol^-1.

33. Calculate the number of atoms in each of the following: (i) 52 moles of Ar (ii) 52 u of He (iii) 52 g of He.

Answer: (i) 1 mole of Ar = 6.022 × 10²³ atoms of Ar

52 mol of Ar = 52 × 6.022 × 10²³ atoms of Ar = 3.131 × 10²⁵ atoms of Ar

(ii) 1 atom of He = 4 u of He
Or, 4 u of He = 1 atom of He

1 u of He = (1/4) atom of He

So, 52u of He = (52/4) atom of He = 13 atoms of He

(iii) 4 g of He = 6.022 × 10²³ atoms of He

52 g of He = [(6.022 × 10²³ x 52)/4] atoms of He = 7.8286 × 10²⁴ atoms of He.

34. A welding fuel gas contains carbon and hydrogen only. Burning a small sample of it in oxygen gives 3.38 g carbon dioxide, 0.690 g of water and no other products. A volume of 10.0 L (measured at STP) of this welding gas is found to weigh 11.6 g. Calculate (i) empirical formula, (ii) molar mass of the gas, and (iii) molecular formula.

Answer: (i) 1 mole (44 g) of CO₂ contains 12 g of carbon.

3.38 g of CO₂ will contain carbon = (¹²/₄₄)*3.38 = 0.9217 g

18 g of water contains 2 g of hydrogen.

0.690 g of water will contain hydrogen = (²/₁₈)*0.690 = 0.0767 g

Since carbon and hydrogen are the only constituents of the compound, so total mass is of carbon and hydrogen only.

Mass of the compound = 0.9217 g + 0.0767 g = 0.9984 g

Percentage of carbon in the compound = (^0.9217/_0.9984)*100 = 92.32 %

Percentage of hydrogen in the compound = (^0.0767/_0.9984)*100 = 7.68 %

Now, the empirical formula of the compound is:

Element	%age	Atomic mass	Mole	Mole ratio	Simplest whole no. ratio
Carbon	92.32	12	92.32/12 = 7.69	7.69/7.68 = 1.001	1
Hydrogen	7.68	1	7.68/1 = 7.68	7.68/7.68 = 1	1

So, the empirical formula of the compound is CH.

(ii) Weight of 10.0 L of the gas (at STP) = 11.6 g

We know that, 1 mole of gas = Molar mass of gas = 22.4 L at STP

So, weight of 22.4 L of gas = ^(11.6*22.4)/₁₀ = 25.98 g = 26 g

Hence, the molar mass of the gas is 26 g/mol.

(iii) Empirical formula mass = 12+1 = 13 g

Molecular mass = 26 g

n = ^{Molecular mass}/_{Empirical formula mass} = ²⁶/₁₃ = 2

Molecular formula = (Empirical formula)_n = (CH)₂ = C₂H₂

Hence, the molecular formula of welding fuel gas is C₂H₂.

35. Calcium carbonate reacts with aqueous HCl to give CaCl₂ and CO₂ according to the reaction,

CaCO₃(s) + 2HCl(aq) → CaCl₂(aq) + CO₂(g) + H₂O(l)

What mass of CaCO₃ is required to react completely with 25 mL of 0.75 M HCl?

Answer: Moles of HCl = Molarity x Volume(L) = 0.75 M x 0.025 L = 0.01875 mol

From the balanced chemical equation, 2 mol HCl reacts with 1 mol CaCO₃

So, 0.01875 mol HCl reacts with CaCO₃ = ^0.01875/₂ = 0.009375 mol

Molar mass of CaCO₃ = 40+12+3(16) = 100 g/mol

Mass of CaCO₃ = Mole*Molar mass = 0.009375 mol * 100 g/mol = 0.9375 g

36. Chlorine is prepared in the laboratory by treating manganese dioxide (MnO₂) with aqueous hydrochloric acid, according to the reaction, 4HCl(aq) + MnO₂(s) → 2H₂O(l) + MnCl₂(aq) + Cl₂(g). How many grams of HCl react with 5.0 g of manganese dioxide?

Answer: From the balanced chemical equation,

1 mol MnO₂ reacts completely with 4 mol of HCl, i.e., 87 g of MnO₂ reacts with 146 g of HCl.

So, 5.0 g of MnO₂ will react with HCl = (¹⁴⁶/₈₇)*5 = 8.4 g

Hence, 8.4 g of HCl will react completely with 5.0 g of MnO₂.

37. What is the SI unit of molarity?

Answer: The SI unit of molarity is mol dm^-3 or mol L^-1, and it is represented as M.

38. What do you mean by stoichiometric coefficients in a chemical equation?

Answer: The coefficients of reactant and product involved in a chemical equation represented by the balanced form, are known as stoichiometric coefficients, e.g., 2H₂ + O₂ → 2H₂O

The stoichiometric coefficients are 2, 1, 2 respectively.

39. Give an example of a molecule in which the ratio of the molecular formula is six times the empirical formula.

Answer: The compound is glucose. Its molecular formula is C₆H₁₂O₆, while its empirical formula is CH₂O.

40. What is an atom according to Dalton’s atomic theory?

Answer: According to Dalton’s atomic theory, an atom is the ultimate particle of matter which cannot be further divided.

41. Why air is not always regarded as homogeneous mixture?

Answer: This is due to the presence of dust particles.

42. Define the term unit of measurement.

Answer: It is defined is the standard of reference chosen to measure a physical quantity.

43. Define the law of conservation of mass.

Answer: It states that matter can neither be created nor be destroyed.

44. How is empirical formula of a compound is related to its molecular formula?

Answer: Molecular formula = (Empirical formula)_n, where n is positive integer.

n is the ratio of molecular mass to the empirical formula mass of that compound.

45. Name two factors that introduce uncertainty into measured figures.

Answer: (i) Reliability of measuring instrument.

(ii) Skill of the person making the measurement.

46. State Avogadro’s law.

Answer: Equal volumes of all gases under the conditions of same temperature and pressure contain the same number of molecules.

47. How are 0.5 m of NaOH different from 0.5 M of NaOH?

Answer: 0.5 m of NaOH means 0.5 mol (20 g) NaOH in 1 Kg of solvent, while 0.5 M means 0.5 mol (20 g) NaOH in 1 L of solution.

48. What is the number of significant figures in 1.050 x 10⁷?

Answer: There are four significant figures.

49. What is ‘1 amu’ or ‘1 u’?

Answer: 1 amu or 1 u is 1/12^th mass of an atom of carbon-12.

50. Define molality. Is molality depend on temperature?

Answer: Molality is defined as the moles of solute per kilogram of solvent.

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

Mass does not change with temperature, so molality is independent of temperature.

51. Why molarity changes with temperature?

Answer: Molarity is defined as number of moles of solute per litre of solution.

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

Volume changes with temperature. The volume increases as the temperature increases, and decreases as the temperature decreases. That’s why molarity changes with temperature.

52. Calculate the number of moles in:

(i) 400 g of sulphuric acid

(ii) 100 L of sulphur dioxide at STP

(iii) 12.044*10²⁴ molecules of oxygen

(iv) 16 g of carbon

Answer: (i) Molar mass of H₂SO₄ = 98 g/mol

Number of moles of sulphuric acid = ^{Given mass}/_{Molar mass} = ⁴⁰⁰/₉₈ mol = 4.082 mol

(ii) 22.4 L of a gas at STP = 1 mol

100 L of SO₂ at STP = ¹⁰⁰/_22.4 mol = 4.464 mol

(iii) 6.022*10²³ molecules of oxygen = 1 mol

12.044*10²⁴ molecules of oxygen = (12.044*10²⁴)/(6.022*10²³) = 20 mol

(iv) Atomic mass of carbon = 12 g

Number of mole of carbon = Given mass/Atomic mass = ¹⁶/₁₂ = 1.333 mol

53. A compound on analysis was found to contain C = 34.6%, H = 3.85% and O = 61.55%. Calculate the empirical formula.

Answer: Calculation of simplest whole number ratio is as follows:

Element	Percentage	Atomic mas	No. of mole	Mole ratio	Simplest whole no.. ratio
C	34.6	12	34.6/12 = 2.88	2.88/2.88 = 1	1*3 = 3
H	3.85	1	3.85/1 = 3.85	3.85/2.88 = 4/3	(4/3)*3 = 4
O	61.55	16	61.55/16 = 3.85	3.85/2.88 = 4/3	(4/3)*3 = 4

The simplest whole number ratio of elements is C:H:O = 3:4:4

So, the empirical formula of the compound is C₃H₄O₄.

54. Calculate: (i) mass of 4 g atom of magnesium (ii) gram atom in 32 g of nitrogen (N).

Answer: (i) 1 g atom of magnesium = 24 g

4 g atom of magnesium = 4*24 = 96 g

(ii) 14 g of N = 1 g atom

32 g of N = 32/14 = 2.29 g atom

55. The density of water at room temperature is 1.0 g/ml. How many molecules are there in a drop of water if its volume is 0.05 ml?

Answer: Volume of drop of water = 0.05 ml

Density of water = 1 g/ml

Mass of water = Density x Volume = 1 g/ml x 0.05 ml = 0.05 g

Molar mass of water = 18 g/mol

Now, 18 g of water = 1 mol

0.05 g of water = ^0.05/₁₈ = 0.0028 mol

1 mol of water contain molecules = 6.022 x 10²³

0.0028 mol of water contain molecules = 6.022 x 10²³ x 0.0028 = 1.68 x 10²¹ molecules.

56. What is the molecular mass of a substance, each molecule of which contains 9 atoms of carbon, 13 atoms of hydrogen and 2.33 x 10^-23 g other component?

Answer: Mass of 9 atoms of carbon = 9 x 12 u = 108 u

Mass of 13 atoms of hydrogen = 13 x 1 u = 13 u

Mass of 2.33 x 10^-23 g of other component = (2.33 x 10^-23)/(1.66 x 10^-24) = 14.04 u

Molecular mass of the substance = 108 + 13 + 14.04 = 135.04 u

57. Calculate the number of carbon and oxygen atoms present in 11.2 L of CO₂ at NTP.

Answer: Step 1: Find the number of CO₂ molecules

22.4 L CO₂ at NTP = 1 mol

11.2 L CO₂ at NTP = 0.5 mol

Now, 1 mol CO₂ = 6.022 x 10²³ molecules

0.5 mol CO₂ = 3.011 x 10²³ molecules

Step 2: Find the carbon and oxygen atoms

1 molecule of CO₂ contain 1 atom of carbon and 2 atoms of oxygen.

Number of carbon atoms in 3.011 x 10²³ molecules of CO₂ = 3.011 x 10²³ atoms

Number of oxygen atoms in 3.011 x 10²³ molecule of CO₂ = 2 x 3.011 x 10²³ = 6.022 x 10²³ atoms.

58. KClO₃ on heating decomposes to give KCl and O₂. What is the volume of O₂ at NTP liberated by 0.1 mole of KClO₃?

Answer: The balanced chemical equation for the decomposition of KClO₃ is: 2KClO₃ → 2KCl + 3O₂

From the chemical equation,

2 mole KClO₃ on decomposition gives 3 mole of O₂

0.1 mole KClO₃ on decomposition gives 0.15 mole of O₂

Volume of 1 mole of a gas at NTP = 22.4 L

Volume of 0.15 mole of O₂ at NTP = 0.15 x 22.4 L =3.36 L

59. 10 ml of a solution of NaCl containing KCl gave on evaporation 0.93 g of the mixed salt which gave 1.865 g of AgCl by reacting with AgNO3 solution. Calculate the quantity of NaCl in 10 ml of the solution.

Answer: The balanced chemical equation for the reaction occurs is: NaCl + AgNO₃ → NaNO₃ + AgCl

Let the mass of NaCl and KCl be p g and q g respectively.

So, p + q = 0.93 g

Let us find AgCl formed on reacting NaCl and KCl with AgNO₃ solution.

From the chemical equation, 58.5 g NaCl give AgCl = 143.5 g

p g of NaCl will give AgCl = (143.5/58.5) *(p) g

Similarly, 74.5 g KCl give AgCl = 143.5 g

q g of KCl will give AgCl = (143.5/74.5) *(q) g

Given that the mass of AgCl actually formed is 1.865 g.

Mass of NaCl in the mixture = p = 0.14 g

Mass of KCl in the mixture = 0.93 – q = 0.93 – 0.14 = 0.79 g

60. The cost of table salt (NaCl) and table sugar (C₁₂H₂₂O₁₁) are Rs. 1 per Kg and Rs. 6 per Kg respectively. Calculate their cost per mole.

Answer: (i) Molar mass of NaCl = 23 + 35.5 + 58.5 g/mol

1000 g of NaCl cost = Rs. 1

So, 58.5 g NaCl cost = (1/1000) x 58.5 = Rs. 0.0585

(ii) Molar mass of C₁₂H₂₂O₁₁ = (12×12)+(22×1)+(11×16) = 342 g/mol

1000 g of C₁₂H₂₂O₁₁ cost = Rs. 6

So, 342 g of C₁₂H₂₂O₁₁ cost = (6/1000) x 342 = Rs. 2.052

61. A flask P contains 0.5 mole of oxygen gas. Another flask Q contains 0.4 mole of ozone gas. Which of the two flasks contains greater number of oxygen atoms?

Answer: We know that, 1 molecule of oxygen gas (O₂) contain 2 oxygen atoms while 1 molecule ozone gas (O₃) contain 3 oxygen atoms.

1 mole of a gas contains 6.022 x 10²³ molecules

In flask P, 0.5 mole of oxygen gas = 0.5 x 6.022 x 10²³ molecules = 0.5 x 6.022 x 10²³ x 2 atoms = 6.022 x 10²³ atoms

In flask Q, 0.4 mole of ozone gas = 0.4 x 6.022 x 10²³ molecules = 0.4 x 6.022 x 10²³ x 3 atoms = 7.23 x 10²³ atoms

Hence, it is clear that flask Q contains greater number of oxygen atoms as compared to flask P.

62. Calculate the total number of electrons present in 1.6 g of methane.

Answer: Mass of methane = 1.6 g

Molar mass of methane = 12 + 4(1) = 16 g/mol

Number of mole of methane = Mass/Molar mass = 1.6/16 = 0.1 mol

1 mole of methane contains 6.022 x 10²³ molecules

So, 0.1 mole of methane contains 6.022 x 10²² molecules.

1 molecule of CH₄ contains 10 electrons, i.e., 6 electrons of carbon atom and 4 electrons of four hydrogen atoms.

Number of electrons in 0.1 mole methane = 6.022 x 10²² x 10 = 6.022 x 10²³ electrons

Hence, the total number of electrons present in 1.6 g of methane are 6.022 x 10²³.

63. The vapour density of a mixture of NO₂ and N₂O₄ is 38.3 at 27°C. Calculate the number of moles of NO₂ in 100 g of the mixture.

Answer: Vapour density of the mixture = 38.3

Molecular mass of mixture = 2 x vapour density = 2 x 38.3 = 76.6 g

Mass of the mixture = 100 g

No. of mole in the mixture = 100/76.6

Let the mass of NO₂ in the mixture = x g

Mass of N₂O₄ in the mixture = (100-x) g

Molar mass of NO₂ = 14 + 32 = 46 g/mol

Molar mass of N₂O₄ = 28 + 64 = 92 g/mol

No. of mole of NO₂ = ^x/₄₆ mol

No. of mole of N₂O₄ = ^(100-x)/₉₂ mol

On solving x = 20.104

Mass of NO₂ = 20.104 g

Mole of NO₂ in the mixture = 20.104/46 = 0.437 mol = 0.44 mol

64. The vapour density of a gaseous element is 5 times of oxygen under similar conditions. If the molecule is triatomic, what will be its atomic mass.

Answer: Molecular mass of oxygen = 32 u

Vapour density of oxygen = Moleculas mass/2 = 32/2 = 16

Vapour density of gaseous molecule = 5 x Vapour density of oxygen = 5 x 16 = 80

Molecular mass of gaseous molecule = 2 x Vapour density = 2 x 80 = 160

The gaseous molecule is triatomic, i.e., its atomicity is 3.

Atomic mass of element = 160/3 = 53.33 u

So, the atomic mass of the element is 53.33 u.

Read more: Conversion in Organic Chemistry Class 12

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