NCERT Solutions for Class 11 Chemistry Chapter 1- Some Basic Concepts of Chemistry

NCERT Solutions for Class 11 Chemistry

Chapter 1- Some Basic Concepts of Chemistry

Q1. Calculate the molar mass of the following: (i) H₂O(ii) CO₂ (iii) CH₄

Ans.

(i) Molar mass of water is calculated as below: 

Mass of one mole of H atoms = 1g/mol

Mass of one mole of O atoms = 16g/mol

Since we have two H atoms and one O atom in H₂O, hence the mass of one mole of H₂O will be = (2×1+16)g/mol = 18g/mol

(ii) Molar mass of Carbon Dioxide is calculated as below: 

Mass of one mole of C atoms = 12g/mol

Mass of one mole of O atoms = 16g/mol

Since we have one atom of C and two atoms of O, hence the molar mass of CO₂ 

will be = (12+16×2) = 44g/mol

(iii)Molar mass of Methane is calculated as below: 

Mass of one mole of C atoms = 12g/mol

Mass of one mole of H atoms = 1g/mol

Since we have one atom of Cand four atoms of H in CH₄, hence the molar mass of

CH₄will be (12+1×4)= 16g/mol

Q2. Calculate the mass per cent of different elements present in sodium sulphate (Na₂SO₄).

Ans.

Molar mass of

Na₂SO₄= [(2 x 23.0) + (32.066) + 4(16.00)]

=142.066 g/mol

Formula to calculate mass percent of an element =

(Mass of element in the compound /total mass of compound) x 100 

Therefore, mass percent of the sodium will be:

=(46.0g /142.066g)×100

= 32.38= 32.4%

Mass percent of the sulphur elementwill be:

=(32.066g/142.066g)×100

= 22.6= 22.6%

Mass percent of the oxygen elementwill be:

=(64.0g/142.066g)×100

= 45.049= 45.05%

Q3. Determine the empirical formula of an oxide of iron, which has 69.9% iron and 30.1% dioxygen by mass.

Ans.

We know that atomic mass of iron is 55.85u and percentage of iron given is 69.9%.

Hence, the relative moles for oxygen in iron oxide will be :

(Percentage of iron / atomic mass of iron)

(69.9/55.85)

= 1.25

Also, the relative moles for oxygenin iron oxide will be :

(Percentage of oxygen/ atomic mass ofoxygen)

(30.1/16)

= 1.88

Hence, the molar ratio of iron to oxygen will be obtained as:

⇒ 1.25: 1.88 ⇒1: 1.5 ⇒2: 3

Hence, the empirical formula of the iron oxide is Fe₂O₃

.

Q4. 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.

Ans.

(i) 1 mole of carbon is burnt in air.

The equation for this will be as:

C + O₂⇒CO₂

From equation we get that 1 mole of carbon reacts with 1 mole of O₂ to form one mole of CO₂. Hence, amount of CO₂ produced = Molar mass of CO₂= 44 g

(ii)1 mole of carbon is burnt in 16 g of O₂.

From above equation we get that1 mole of carbon reacts with 1 mole (32g) of O₂ to form 44g of CO₂. Hence the amount of CO₂ produced when 1 mole of carbon is burnt in 16 g of dioxygen = (44×16)/32 = 22g

(iii) 2 moles of carbon are burnt in 16 g of O₂.

Since 16 g of O₂ gives 22g of CO₂, and also here, the O₂ is the limiting reactant. So in this case too, CO₂ produced will be 22g.

Q5.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. 

Ans.

0.375 M aqueous solution of CH₃COONa means that 0.375 moles of CH₃COONa is present in 1000 mL of solution.

Hence the number of moles of CH₃COONa present in 500 ml of soln. will be

(0.375×500)/1000

= 0.1875 mole

Now it is given that molar mass of CH₃COONa is 82.0245g/mol which means that mass of one mol of CH₃COONa = 82.0245g

Thus, mass of 0.1875 mol of CH₃COONa= (82.02×0.1875) g= 15.378g

Q6. 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%

Ans.

In this question, firstly we will calculate the Molar mass of HNO_3.

Molar mass of HNO₃ = {1 + 14 + 3(16)} g/mol = 63g/mol.

Mass of given sample = volume×density = 1.41g

Now, percentage of nitric acid present = 69%

So, mass of nitric acid present in sample = (1.41×69)/100 =0.973g

Now since, 63g is the mass of 1 mol of NHO₃

Therefore, 0.973g will be mass of (0.973g/63g)mol = 0.01544 mol of HNO₃.

Now, 1 ml of soln. contains 0.01544 mol of HNO₃

Thus, 1000ml(1L) of soln. contains = (1000*0.01544)mol of HNO₃.

Hence, concentration of nitric acid in moles per litre= 15.44mol/L.

Q7. How much copper can be obtained from 100 g of copper sulphate (CuSO₄)?

Ans.

From the chemical formula of CuSO₄, we see that one CuSO₄molecule has one Cu atom.

Hence, one mole of CuSO₄will contain 1 mole of Cu atoms.

Now we will calculate the molar mass of CuSO₄.

Molar mass of CuSO₄= {63.5 + 32.00 + 4(16.00)}g/mol = 159.5 g/mol

So, 159.5 g of CuSO₄ contains 63.5g of Cu.

Thus, 100g of CuSO₄ will contain {(100*63.5)/159.5}g = 39.81g

Q8. Determine the molecular formula of an oxide of iron, in which the mass percent of iron and oxygen are 69.9 and 30.1, respectively. 

Ans.

Here,

Mass percent of Fe = 69.9%

Mass percent of O = 30.1%

Since 55.85g is the mass of 1 mole of Fe.

Thus, 69.9g will be the mass of (69.9/55.85)g = 1.25g of Fe

Similarly,

No. of moles of O present in oxide=(30.1/16.0)g =1.88g of O

So, we get the ratio of Fe to O in oxide as,

= 1.25: 1.88

=1:1.5

=2:3

Therefore, the empirical formula of oxide isFe₂O₃

Also, the Empirical formula mass ofFe₂O₃= {2(55.85) + 3(16.00)} g= 159.7g

And the molar mass of Fe₂O₃= 159.69g

Therefore n = (Empirical formula mass/ molar mass) = 0.999≈ 1

The molecular formula = n * empirical formula.

Thus, the empirical of the given oxide isFe₂O₃and n obtained is 1.

Thus, the molecular formula of the oxide is Fe₂O₃ 

Q9. Calculate the atomic mass (average) of chlorine using the following data:

Percentage Natural Abundance		Molar Mass
35Cl	75.77	34.9689
37Cl	24.23	36.9659

Ans.

Abundance of ³⁵Cl = 75.77% = 0.7577 and Molar mass = 34.9689g/mol

Since molar mass is numerically equal to atomic mass,so,

Atomic massof ³⁵Cl = 34.9689u. 

Abundance of ³⁷Cl = 24.23% = 0.2423 and Molar mass = 36.9659g/mol

Atomic mass of ³⁷Cl = 36.9659u. 

Average Atomic mass can be calculated as = {(0.7577 x 34.9689) + (0.2423 x 36.9659)}u= 26.4959 + 8.9568 = 35.4527u

Q10. In three moles of ethane (C₂H₆), calculate the following:
(i) Number of moles of carbon atoms.
(ii) Number of moles of hydrogen atom

(iii) Number of molecules of ethane

Ans.

(i) Since we can see that in one molecule of ethane(C₂H₆), two carbon atoms are present. So, in one mole of ethane, two moles of carbon atoms will be present.

Therefore, in three moles of ethane, (3×2) = 6 moles of carbon atoms will be present.

(ii)In one molecule of ethane(C₂H₆), six Hydrogen atoms are present. So, in one mole of ethane, six moles of Hydrogen atoms will be present.

Therefore, in three moles of ethane, (3×6) = 18 moles of Hydrogen atoms will be present.

(iii) In one mole of ethane, number of molecules present = 6.023x 10²³molecules

Hence, in three moles of ethane, number of molecules present = 3×6.023x 10²³

= 18.069 x 10²³ molecules.

Q11. What is the concentration of sugar (C₁₂H₂₂O₁₁) in mol L^–1 if its 20 g are dissolved in enough water to make a final volume up to 2L?

Ans.

In this question, first we will calculate the moles of solute.

Molar mass of sugar(C₁₂H₂₂O₁₁) = 342.2965g/mol

So, no. of moles of sugar = (20g/342g) = 0.0585 mol

Thus, molarity is given as (no. of moles of solute)/ (Volume of Soln. in Litres)

Therefore, Molarity = (0.0585/2)mol/L = 0.02925 mol/L

Q12. If the density of methanol is 0.793 kg L^–1, what is its volume needed for making 2.5 L of its 0.25 M solution?

Ans.)

Mass of methanol required is

mass=Volume of solution×Molarity of the solution×Molar mass of methanol

=2.5×0.25×32=20 g.

Therefore,
Volume of methanol needed =mass/density=20/0.793=25.22 ml.

Q13. Pressure is determined as force per unit area of the surface. The SI unit of pressure, pascal is as shown below:
1Pa = 1N m^–2
If mass of air at sea level is 1034 g cm^–2, calculate the pressure in pascal

Ans.

Pressure is the force acting per unit area of the surface.

But weight = mg

∴ Pressure = Weight per unit area

Pressure = weight per unit area =mg

=1034g/cm²×(1kg/1000g)×(100cm²/1m)×9.80m/s²×(1N/kgm/s²)×(1Pa /1N/m²)

=1.013×10⁵Pa

Q14. What is the SI unit of mass? How is it defined?

Ans.

The SI unit of mass is kilogram (kg). It has been defined as the mass of platinum-iridium (Pt-Ir) cylinder that is stored in an airtight jar at International Bureau of Weights and Measures in Sevres, France.

Q15. Match the following prefixes with their multiples:

	Prefixes	Multiples
(a)	Femto	10
(b)	Giga	10−15
(c)	Mega	10−6
(d)	Deca	109
(e)	Micro	106

Ans.

	Prefixes	Multiples
(a)	femto	10−15
(b)	giga	109
(c)	mega	106
(d)	deca	10
(e)	micro	10−6

Q16. What do you mean by significant figures?

Ans.

Significant figures are meaningful digits which are known with certainty plus one which is estimated or uncertain.

For e.g.: Suppose you obtain a result of the experiment as75.3 ml. So, in this case 75is certain and 3 is uncertainand the uncertainty would be +/-(1) in the last digit(3 in this case). So, the total significant figures are 3.

Q17. 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 per cent by mass.
(ii) Determine the molality of chloroform in the water sample.

Ans.

(i) 1 ppm is defined as 1 part out of 1 million parts.

Mass percent of 15 ppm chloroform in H2O

=(15/10⁶) ×100

≈1.5 ×10⁻³%

(ii) Molar mass of CHCl₃ = 119.38 g/mol

So, moles of CHCl₃ present in sample = (15/119.38)mol = 0.125 mol

Therefore, molality = 0.125 mol/ 1000g = 1.25 × 10^-4 mol/kg

Q18. Express the following in the scientific notation:
(i) 0.0048
(ii) 234,000
(iii) 8008
(iv) 500.0
(v) 6.0012

Ans.

Scientific notation is a way of writing numbers that are either very large or very small. A number is written in scientific notation when a number between 1 and 10 is multiplied by a power of 10.

(i) 0.0048= 4.8 ×10⁻³

(ii) 234,000 = 2.34 ×10⁵

(iii) 8008= 8.008 ×10³

(iv) 500.0 = 5.000 ×10²

(v) 6.0012 = 6.0012 ×10⁰

Q19. How many significant figures are present in the following?

(a) 0.0025

(b) 208

(c) 5005

(d) 126,000

(e) 500.0

(f) 2.0034

Ans.

(a) 0.0025: 2 significant numbers (zeros to the left of 1^st non-zero digit are insignificant).

(b) 208: 3 significant numbers (zeros between two non-zero digits are significant).

(c) 5005: 4 significant numbers(zeros between two non-zero digits are significant).

(d) 126,000:3 significant numbers(zeros to the left of decimal and right of non-zero digit are insignificant).

(e) 500.0: 4 significant numbers(zeros to the right of decimal are significant and also, non-zero digit to the left of decimal is significant. So both the middle zeros are present between significant numbers.)

(f) 2.0034: 5 significant numbers(same explanation as above)

Q20. Round up the following upto three significant figures:

(a) 34.216

(b) 10.4107

(c)0.04597

(d)2808

Ans.

(a) The number we will get after round up: 34.2

(b) The number we will get after round up: 10.4

(c)The number we will get after round up: 0.046

(d)The number we will get after round up: 281

Q21. The following data are obtained when dinitrogen and dioxygen react together to form different compounds:

	Mass of dioxygen	Mass of dinitrogen
(i)	16 g	14 g
(ii)	32 g	14 g
(iii)	32 g	28 g
(iv)	80 g	28 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

Ans.

(a)

Upon fixing the mass of dinitrogen at 14g, the masses of dioxygen that are going to combine with the given fixed mass of dinitrogen are 16g, 32g, 32g, and 80g.

The masses of dioxygen are in a whole number ratio of 1:2:2:5.

Therefore, we can say that the given experimental data obeys the Law of Multiple Proportions.

(b)

 (i) 1 km = 10⁶mm = 10¹⁵ pm
(ii) 1 mg = 10^-6kg = 10⁶ ng
(iii) 1 mL = 10^-3 L =10^-3 dm³

Q22. If the speed of light is 3.0 × 108 m s–1, calculate the distance covered by light in 2.00 ns.

Ans.

The given time is in ns, so firstly we will convert it in s.

Time taken = 2 ns= 2 ×10⁻⁹s

Now,

Speed of light = 3 ×10⁸ m/s

Now,

Distance = Speed x Time

So,

Distance travelled in 2 ns = speed of light x time taken by light

= (3 ×10⁸)(2 ×10⁻⁹) m

= 6 ×10^-1m

= 0.6 m

Q23. 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

Ans.

Limiting reagentis the first to get fully consumed during a reaction, thus causes the reaction to stop and limits the amount of product formed.It determines the extent of a reaction.

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

1 atom of A reacts with 1 molecule of B.

So, 200 atoms of A reacts with 200 molecules of B,

Therefore 100 atoms of A remain unconsumed and B is consumed fully.

Hence, B is the limiting reagent.

(ii) 2 mol A + 3 mol B

1 mole of A reacts with 1 mole of B.

So, 2 moles of A reacts with 2 moles of B, so 1 mole of B is unused whereas A is consumed fully.

Hence, A is the limiting reagent.

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

1 atom of A reacts with 1 molecule of B.

So, 100 atoms of A will react with 100 molecules of B. Hence  there will be no limiting reagent as it is a stoichiometric mixture.

(iv) 5 mol A + 2.5 mol B

1 mole of A reacts with 1 mole of B.

So, 2.5 moles of A reacts with 2.5 moles of B, so 2.5 moles of A is unused whereas B is consumed fully.

Hence, B is the limiting reagent.

(v) 2.5 mol A + 5 mol B

1 mole of A reacts with 1 mole of B.

So, 2.5 moles of A reacts with 2.5 moles of B, so 2.5 moles of B is unused whereas A is consumed fully.

Hence, A is the limiting reagent.

Q24. Dinitrogen and dihydrogen react with each other to produce ammonia according to the following chemical equation:
N₂ (g) + H₂(g)→ 2NH₃ (g)

(i) Calculate the mass of ammonia produced if 2.00 × 10³ g dinitrogen reacts with 1.00 × 10³ g of dihydrogen.

 (ii) Will any of the two reactants remain unreacted?

(iii) If yes, which one and what would be its mass.

Ans.

(i) From a balanced equation, we have,

N₂ (g) +3H₂(g)→ 2NH₃ (g)

Hence, we can say that 1 mol(28g) of N₂ reacts with 3 mol(6g) of H₂.

∴ 2000 g of N₂ will react with (6g × 2000g)/28g    = 428.6g of H₂

Now, 28g of N₂ produces 34g of NH₃

Hence, 2000g of N₂ produces (34 ×2000) / 28 = 2428.57g of NH₃

Hence, here, N₂ will get consumed fully and H₂will remain unreacted.

(ii) H₂ will remain unreacted

(iii) Mass of H₂ left unreacted = 1000g – 428.6g = 571.4g

Q25. How are 0.50 mol Na₂CO₃ and 0.50 M Na₂CO₃ different?

Ans.

Molar mass of Na₂CO₃

= (2 × 23) + 12 + (3 × 16)

= 106 g/mol

So, 1 mole of Na2CO3 means 106 g of Na2CO3

Thus, 0.5 mol of Na₂CO₃= (0.5 ×106)= 53 g of Na₂CO₃

Now, M denotes the molarity of the solution.

So,

0.5 M ofNa₂CO₃ = 0.5 mol/L of Na₂CO₃

Hence, 0.5 mol of Na₂CO₃ is in 1 L of water or 53 g ofNa₂CO₃ is in 1 L of water.

So, both are different in the way that the first one is just giving the mass of Na₂CO₃ whereas the second one is giving the mass dissolved per litre of solution.

Q26. If 10 volumes of dihydrogen gas reacts with five volumes of dioxygen gas, how many volumes of water vapour would be produced?

Ans.

From a balanced chemical equation, we see that,

2 H₂ + O₂ → 2 H₂O 

So, 2 volumes of dihydrogen react with 1 volume of dioxygen to produce two volumes of water vapour.

Therefore, we can say that 10 volumes of dihydrogen will react with five volumes of dioxygen to produce 10 volumes of water vapour.

Q27. Convert the following into basic units:

(i) 28.7 pm

(ii) 15.15 pm

(iii) 25365 mg

Ans.

(i) 28.7 pm

We know that,

1 pm = 10⁻¹²m

Therefore, 28.7 pm = (28.7 ×10⁻¹²) m = 2.87 ×10⁻¹¹ m

(ii) 15.15 pm

We know that,

1 pm = 10⁻¹²m

Therefore, 15.15 pm = (15.15 ×10⁻¹²) m = 1.515 ×10⁻¹¹ m

(iii) 25365 mg

We know that,

1 mg= 10⁻⁶ kg

Therefore, 25365 mg = (25365×10⁻⁶) kg = 2.5365×10⁻²kg

Q28. Which one of the following will have the largest number of atoms?

(i) 1 g Au (s)

(ii) 1 g Na (s)

(iii) 1 g Li (s)

(iv) 1 g ofCl₂(g)

Ans.

(i) 1 g of Au (s)

Since, 197g of Au contains 6.022×10²³ atoms of Au.

Therefore, 1g of Au contains (6.022×10²³)/197 = 3.06×10²¹ atoms of Au.

(ii) 1 g of Na (s)

Since, 23g of Na contains 6.022×10²³atoms of Na.

Therefore, 1g of Na contains (6.022×10²³)/23 = 26.2×10²¹ atoms of Na.

(iii) 1 g of Li (s)

Since, 7g of Li contains 6.022×10²³atoms of Li.

Therefore, 1g of Li contains (6.022×10²³)/7 = 86 ×10²¹ atoms of Li

(iv)1 g ofCl₂(g)

Since, 71g of Cl₂contains 6.022×10²³ atoms of Cl₂.

Therefore, 1g of Cl₂contains (6.022×10²³)/71 = 8.48×10²¹molecules of Cl₂ = 16.96×10²¹atoms of Cl

Therefore, 1 g of Li (s) will have the largest no. of atoms.

Q29. 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 to be one).

Ans.

We know the mole fraction of ethanol is defined as the ratio of the number of moles of ethanol to the total number of moles present in the solution.

Now,1 L of water contains 1000/18=55.55 moles of water.

Given, the mole fraction of ethanol is 0.040.

Let n be the number of moles of ethanol.

So we have, 0.040=n/ (n+55.55)

n=0.040n+2.222

n=(2.222)/(1−0.040)=2.31 moles.

As 1 L of solution contains 2.31 moles of ethanol, the molarity of a solution is 2.31 M.

Q30. What will be the mass of one 12C atom in g?

Ans.

We know that the molar mass of Carbon is 12g/mol

So, we can say that,

6.022 × 10²³atoms of carbon has mass = 12g

So, 1 atom of carbon has mass = 12 / (6.022× 10²³) g

                                                   = 1.993 × 10^-23g

Q31. How many significant figures should be present in the answer of the following calculations?

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

Ans.

(i)(0.02856×298.15×0.112) / 0.5785

Here, the least precise number is = 0.112

Therefore, no. of significant numbers= no. of significant numbers in 0.112

= 3

(ii) 5 × 5.364

Here we have got the least precise number = 5.364

Therefore, no. of significant numbers= no. of significant numbers in 5.364

= 4

(iii) 0.0125 + 0.7864 + 0.0215

Here, the no. of significant numbers in the answer will be 4 as the least no. of decimal place in each term is 4.

Q32. Use the data given in the following table to calculate the molar mass of naturally occurring argon isotopes:

Isotope	Molar mass	Abundance
36Ar	35.96755g mol–1	0.337 %
38Ar	37.96272g mol–1	0.063 %
40Ar	39.9624g mol–1	99.600 %

Ans.

Molar mass of Argon:

= [

{35.96755× (0.337/100)}

+

{37.96272× (0.063/100)}

+

{39.9624× (99.600/100)}]

= [0.121 + 0.024 + 39.802]g/mol

= 39.947 g/mol

Q33. 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

Ans.

(i)We know that,

1 mole of Ar =6.023×10²³atoms of Ar

Therefore, 52 moles of Ar = 52 ×6.023×10²³atoms of Ar

=3.131×10²⁵atoms of Ar

(ii) 52 u of He

We know that,

4 u of He = 1 atom of He

1 u of He =1/4atom of He

Or, 52 u of He =52/4atoms of He= 13 atoms of He

(iii) 52 g of He

We know that,

4 g of He =6.023×10²³atoms of He

52 g of He = (6.023×10²³×52)/4atoms of He

=7.829×10²⁴atoms of He

Q34. 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.  Find:

(i) Empirical formula

(ii) Molar mass of the gas, and

(iii) Molecular formula

Ans.

Since, 3.38 g of carbon dioxide are obtained, the mass of C in the sample of welding fuel gas can be obtained as
(12/44)×3.38=0.92 g.

Also, 0.690 g of water are obtained, so, the mass of hydrogen present in the weldingsample is
(2/18)×0.690=0.077g.
The percentage of C is {0.92/(0.92+0.077)}×100=92.3 %.
The percentage of H is {0.077/(0.92+0.077)}×100=7.7%.

(i) So we get no. of moles of Carbon =92.3/12=7.7.
no. of moles of hydrogen =7.7/1=7.7.
Hence, the mole ratio C:H=7.7/7.7=1:1.
Therefore, we can say the empirical formula of the welding fuel gas is CH.

(ii) The weight of 10.0 L of gas at N.T.P is 11.6 g.
The weight of 22.4 L of gas at N.T. P = (11.6/10.0)×22.4=26g/mol

(iii) Empirical formula(CH)  mass is 12+1=13.
Molecular mass is 26 (calculated above).
The ratio of the molecular mass to empirical formula mass is 26/13=2.
Therefore, we get molecular formula as 2(CH)=C₂H₂.

Q35. Calcium carbonate reacts with aqueous HCl to give CaCl₂ and CO₂ according to the reaction, CaCO₃ (s) + 2 HCl (aq) →  CaCl₂(aq) + CO₂ (g) + H₂O(l)

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

Ans.

The meaning of 0.75 M HCL is that 0.75mol of HCL is present in 1 L of solution.

Now, 1 mol of HCl = (1+35.5) g = 36.5g

∴0.75 mol of HCl = (36.5 ×0.75)g = 27.375g

So, 1000ml of HCL contains 27.375gofHCl.

Thus, 25ml of HCL contains (25 ×27.375)/1000 = 0.684g of HCl.

Now, from eq. we get that 2 mols of HCL react completely with 1 mol of CaCO₃

Or, (2×36.5) g of HCL react with 100g of CaCO₃(molar mass of CaCO₃is100)

∴0.684g of HCL will react with (0.684×100) /(2×36.5) = 0.937g of CaCO₃

Q36. Chlorine is prepared in the laboratory by treating manganese dioxide (MnO₂) with aqueous hydrochloric acid according to the reaction:

4 HCl (aq) + MnO₂(s) → 2H₂O (l) + MnCl₂(aq) + Cl₂ (g)

How many grams of HCl react with 5.0 g of manganese dioxide?

Ans.

In this question, firstly we will find out the mass of one mole of MnO₂.

Mass of one mole of MnO₂= 55+ 2 ×16 = 87g

Also, from the above eq., it is clear that 1 mole of MnO₂reacts with 4 moles of HCL.

So, mass of 4 moles of HCL = 4× (1+35.5) = 146g

So, 87g of MnO₂reacts with 146g of HCL.

Therefore, 5g of MnO₂reacts with (5×146)/87 = 8.4g HCL.