Question

NCERT Solutions Class 11 Physics Chapter 9 Mechanical Properties of Solids very important chapter of class 11. Our solution is made by the expert on the subject. These NCERT solutions are very concise and explained in very easy-to-understand language. An in-depth understanding of the chapter will help students gain clarity in the concepts of physics.

In this NCERT Solutions Class 11 Physics Chapter 9,  we have discussed all kinds of questions including exercise questions and intext questions, as well as the questions at the back of the chapter.  This is very helpful in completing assignments, and homework and tackling tough questions. Important topics discussed in this chapter are:

• Mechanical properties of solids include:
  • Elasticity – The ability of an object to regain its shape after it is stretched.
  • Plasticity – The ability of an object to change its shape without breaking and never coming back to its original shape is termed plasticity.
  • Ductility – The property of a material by which it can be drawn into the thin wire is known as ductility. Gold is the most ductile material.
  • Strength – the ability of an object to sustain the applied stress without any failure.
• Stress – stress is the force acting on a unit area. There are different kinds of stress:
  • Longitudinal Stress
    • Tensile stress
    • Compressive stress
  • tangential or shearing stress
  • Hydraulic stress
• Strains – the amount of deformation experienced or how much an object is stretched in the direction of force is called strain. There are 3 different kinds of strain:
  • Longitudinal Strain
  • Shearing Strain
  • Volume Strain
• Hooke’s Law – Hooke’s law explains the force needed to extend or compress a spring by a distance linearly. It was named after the scientist Robert Hooke.
• Stress-Strain curve - When stress and stress are drawn along the y-axis and x-axis respectively, a linear graph is formed in the ideal situation of Hooke’s law but the actual experiments are drawn, and a curve is formed.
• Microscopic Description – A description of what a matter constitutes at the basic level.
• Classes of Solids –
  • Ionic solid – sodium chloride
  • Covalent solid – diamond
  • Metallic bonding – gold, silver

In this NCERT Solutions Class 11 Physics Chapter 9 Mechanical Properties Of Solids we have discussed every concept with a holistic approach. Our experts at Sarthaks suggest learning and revising the questions and answers to score good marks in the exam.

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Answer 1

NCERT Solutions Class 11 Physics Chapter 9 Mechanical Properties Of Solids

1. A steel wire of length 4.7 m and cross-sectional area 3.0 × 10^–5 m² stretches by the same amount as a copper wire of length 3.5 m and cross-sectional area of 4.0 × 10^–5 m² under a given load. What is the ratio of the Young’s modulus of steel to that of copper? 

Solution:

Length of the steel wire, L₁ = 4.7 m 

Area of cross-section of the steel wire, A₁ = 3.0 × 10^–5 m² 

Length of the copper wire, L₂ = 3.5 m 

Area of cross-section of the copper wire, A₂ = 4.0 × 10^–5 m² 

Change in length = ΔL₁ = ΔL₂ = ΔL 

Force applied in both the cases = F 

Young’s modulus of the steel wire:

Young’s modulus of the copper wire:

Dividing (i) by (ii), we get:

The ratio of Young’s modulus of steel to that of copper is 1.79: 1.

2. Figure shows the strain-stress curve for a given material. What are (a) Young’s modulus and (b) approximate yield strength for this material?

Solution: 

It is clear from the given graph that for stress 150 × 10⁶ N/m² , strain is 0.002. 

a) Young’s modulus, Y = \(\frac {Stress}{Strain}\)

= \(\frac {150\times10^6}{0.002} = 7.5 \times10^{10}\)N/m²

Hence, Young’s modulus for the given material is 7.5 ×10¹⁰ N/m² . 

b) The yield strength of a material is the maximum stress that the material can sustain without crossing the elastic limit. 

It is clear from the given graph that the approximate yield strength of this material is 300 × 10⁶ N/m² or 3 × 10⁸ N/m².

3. The stress-strain graphs for materials A and B are shown in Figure.

The graphs are drawn to the same scale. 

a) Which of the materials has the greater Young’s modulus? 

b) Which of the two is the stronger material?

Solution:

(a) A 

(b) A 

For a given strain, the stress for material A is more than it is for material B, as shown in the two graphs. 

Young’s modulus =  \(\frac {Stress}{Strain}\) 

For a given strain, if the stress for a material is more, then Young’s modulus is also greater for that material. Therefore, Young’s modulus for material A is greater than it is for material B. 

The amount of stress required for fracturing a material, corresponding to its fracture point, gives the strength of that material. Fracture point is the extreme point in a stress-strain curve. It can be observed that material A can withstand more strain than material B. 

Hence, material A is stronger than material B.

4. Read the following two statements below carefully and state, with reasons, if it is true or false. 

a) The Young’s modulus of rubber is greater than that of steel; 

b) The stretching of a coil is determined by its shear modulus. 

Solution:

(a) False 

(b) True 

For a given stress, the strain in rubber is more than it is in steel. 

Young’s modulus, Y = \(\frac {Stress}{Strain}\) 

For a constant stress: ∝ \(\frac {1}{Strain}\)

 Hence, Young’s modulus for rubber is less than it is for steel. 

Shear modulus is the ratio of the applied stress to the change in the shape of a body. The stretching of a coil changes its shape. Hence, shear modulus of elasticity is involved in this process. 

5. Two wires of diameter 0.25 cm, one made of steel and the other made of brass are loaded as shown in Figure. The unloaded length of steel wire is 1.5 m and that of brass wire is 1.0 m. Compute the elongations of the steel and the brass wires.

Solution:

Elongation of the steel wire = 1.49 × 10^–4 m

Elongation of the brass wire = 1.3 × 10^–4 m 

Diameter of the wires, d = 0.25 m 

Hence, the radius of the wires, r = d/2= 0.125 cm 

Length of the steel wire, L₁ = 1.5 m 

Length of the brass wire, L₂ = 1.0 m 

Total force exerted on the steel wire: 

F₁ = (4 + 6) g = 10 × 9.8 = 98 N 

Young’s modulus for steel:

Where,

△L₁ = Change in the length of the steel wire

A₁ = Area of cross-section of the steel wire = \(\pi r^2_1\) 

Young's modulus of steel,  Y₁ = 2.0 x 10¹¹ Pa

Total force on the brass wire:

F₂ = 6 x 9.8 = 58.8 N

Young's modulus for brass:

Y₂ = \(\frac {(\frac {F_2}{A_2})}{(\frac {\triangle L_2}{L_2})}\)

Where,

△L₂ = Change in length

A₂ = Are of cross-section of the brass wire

Elongation of the steel wire = 1.49 × 10^–4 m 

Elongation of the brass wire = 1.3 × 10^–4 m

Answer 2

6. The edge of an aluminium cube is 10 cm long. One face of the cube is firmly fixed to a vertical wall. A mass of 100 kg is then attached to the opposite face of the cube. The shear modulus of aluminium is 25 GPa. What is the vertical deflection of this face? 

Solution:

Edge of the aluminium cube, L = 10 cm = 0.1 m 

The mass attached to the cube, m = 100 kg 

Shear modulus (η) of aluminium = 25 GPa = 25 × 10⁹ Pa

Shear modulus, η = \(\frac {Shear\, stress}{Shear \, strain} = \frac {\frac FA}{\frac {L}{\triangle L}}\)

Where, 

F = Applied force = mg = 100 × 9.8 = 980 N 

A = Area of one of the faces of the cube = 0.1 × 0.1 = 0.01 m² 

ΔL = Vertical deflection of the cube

∴ △L = \(\frac {FL}{Aη}\)

= \(\frac {980\times 0.1}{10^{-2}\times (25\times10^9)}\) 

= 3.92 × 10^–7 m 

The vertical deflection of this face of the cube is 3.92 ×10^–7 m.

7. Four identical hollow cylindrical columns of mild steel support a big structure of mass 50,000 kg. The inner and outer radii of each column are 30 cm and 60 cm respectively. Assuming the load distribution to be uniform, calculate the compressional strain of each column.

Solution:

Mass of the big structure, M = 50,000 kg 

Inner radius of the column, r = 30 cm = 0.3 m 

Outer radius of the column, R = 60 cm = 0.6 m

Young’s modulus of steel, Y = 2 × 10¹¹ Pa 

Total force exerted, F = Mg = 50000 × 9.8 N

Stress = Force exerted on a single column = \(\frac {50000\times9.8}{4}\) = 122500 N

Young’s modulus, Y = \(\frac {Stress}{Strain}\)

Strain = \(\frac {\frac FA}{Y}\) 

Where, Area, A = π (R² – r² ) = π ((0.6)² – (0.3)² )

Hence, the compressional strain of each column is 7.22 × 10^–7.

8. A piece of copper having a rectangular cross-section of 15.2 mm × 19.1 mm is pulled in tension with 44,500 N force, producing only elastic deformation. Calculate the resulting strain? 

Solution:

Length of the piece of copper, l = 19.1 mm = 19.1 × 10^–3 m 

Breadth of the piece of copper, b = 15.2 mm = 15.2 × 10^–3 m 

Area of the copper piece: 

A = l × b = 19.1 × 10^–3 × 15.2 × 10^–3 = 2.9 × 10^–4 m² 

Tension force applied on the piece of copper, F = 44500 N

Modulus of elasticity of copper, η = 42 × 10⁹ N/m²

Modulus of elasticity, η = \(\frac {Stress}{Strain}\) = \(\frac {\frac FA}{Strain}\) 

∴ Strain = \(\frac F{Aη}\)

= \(\frac {44500}{2.9 \times 10^{-4} \times 42 \times 10^9}\)

= 3.65 × 10^–3

9. A steel cable with a radius of 1.5 cm supports a chairlift at a ski area. If the maximum stress is not to exceed 10⁸ N m^–2 , what is the maximum load the cable can support?

Solution:

Radius of the steel cable, r = 1.5 cm = 0.015 m

Maximum allowable stress = 10⁸ N m^-2

Maximum stress = \(\frac {Maximum\, force}{Area\,of\, cross-section}\) 

∴ Maximum force = Maximum stress x Area of cross-section

= 10⁸ x π (0.015)²

= 7.065 x 10⁴ N

Hence, the cable can support the maximum load of 7.065 x 10⁴ N

10. A rigid bar of mass 15 kg is supported symmetrically by three wires each 2.0 m long. Those at each end are of copper and the middle one is of iron. Determine the ratio of their diameters if each is to have the same tension. 

Solution:

The tension force acting on each wire is the same. Thus, the extension in each case is the same. Since the wires are of the same length, the strain will also be the same. The relation for Young’s modulus is given as:

Y = \(\frac {Stress}{Strain}\) = \(\frac {\frac FA}{Strain}\) = \(\frac {\frac {4F}{\pi d^2}}{Strain}\) ...(i)

Where, 

F = Tension force 

A = Area of cross-section

d = Diameter of the wire

It can be inferred from equation (i) that Y ∝ \(\frac 1{d^2}\) 

Young's modulus for iron, Y₁ = 190 x 10⁹ Pa

Diameter of the iron wire = d₁

Young's modulus for copper, Y₂ = 110 x 10⁹ Pa

Diameter of the copper wire = d₂

Therefore, the ration of their diameters is given as:

Answer 3

11. A 14.5 kg mass, fastened to the end of a steel wire of unstretched length 1.0 m, is whirled in a vertical circle with an angular velocity of 2 rev/s at the bottom of the circle. The cross-sectional area of the wire is 0.065 cm² . Calculate the elongation of the wire when the mass is at the lowest point of its path. 

Solution:

Mass, m = 14.5 kg 

Length of the steel wire, l = 1.0 m 

Angular velocity, ω = 2 rev/s 

Cross-sectional area of the wire, a = 0.065 cm² 

Let δl be the elongation of the wire when the mass is at the lowest point of its path. 

When the mass is placed at the position of the vertical circle, the total force on the mass is: 

F = mg + mlω² 

= 14.5 × 9.8 + 14.5 × 1 × (2)² = 200.1 N

Young's modulus = \(\frac {Stress}{Strain}\)

Young’s modulus for steel = 2 × 10¹¹ Pa

Hence, the elongation of the wire is 1.539 × 10^–4 m

12. Compute the bulk modulus of water from the following data: Initial volume = 100.0 litre, Pressure increase = 100.0 atm (1 atm = 1.013 × 10⁵ Pa), Final volume = 100.5 litre. Compare the bulk modulus of water with that of air (at constant temperature). Explain in simple terms why the ratio is so large. 

Solution: 

Initial volume, V₁ = 100.0l = 100.0 × 10^–3 m³ 

Final volume, V₂ = 100.5 l = 100.5 ×10^–3 m³ 

Increase in volume, ΔV = V₂ – V₁ = 0.5 × 10^–3 m³ 

Increase in pressure, Δp = 100.0 atm = 100 × 1.013 × 10⁵ Pa

= 2.026 x 10⁹ Pa

Bulk modulus of air = 1.0 x 10⁵ PA

This ratio is very high because air is more compressible than water.

13. What is the density of water at a depth where pressure is 80.0 atm, given that its density at the surface is 1.03 × 10³ kg m^–3 ? 

Solution:

Let the given depth be h. 

Pressure at the given depth, p = 80.0 atm = 80 × 1.01 × 10⁵ Pa 

Density of water at the surface, ρ₁ = 1.03 × 10³ kg m^–3 

Let ρ₂ be the density of water at the depth h. 

Let V₁ be the volume of water of mass m at the surface. 

Let V₂ be the volume of water of mass m at the depth h. 

Let ΔV be the change in volume.

△V = V₁ - V₂

Compressibility of water = \(\frac 1B\) = 45.8 x 10^-11 Pa^-1

∴ \(\frac {△V}{V_1}\) = 80 x 1.013 x 10⁵ x 45.8 x 10^-11 = 3.71 x 10^-3 ...(ii)

For equations (i) and (ii), we get:

= 1.034 x 10³ kg m^-3

Therefore, the density of water at the given depth (h) is 1.034 × 10³ kg m^–3.

14. Compute the fractional change in volume of a glass slab, when subjected to a hydraulic pressure of 10 atm. 

Solution: 

Hydraulic pressure exerted on the glass slab, p = 10 atm = 10 × 1.013 × 10⁵ Pa 

Bulk modulus of glass, B = 37 × 10⁹ Nm^–2

Bulk modulus, B = \(\frac {\frac P{△V}}{V}\)

Where,

\(\frac {△V}{V}\) = Fractional change in volume

∴ \(\frac {△V}{V}\) = \(\frac pB\) 

= \(\frac {10\times1.013\times10^5}{37\times10^9}\) 

= 2.73 x 10^-5

Hence, the fractional change in the volume of the glass slab is 2.73 × 10^–5.

15. Determine the volume contraction of a solid copper cube, 10 cm on an edge, when subjected to a hydraulic pressure of 7.0 ×10⁶ Pa.

Solution:

Length of an edge of the solid copper cube, l = 10 cm = 0.1 m

Hydraulic pressure, p = 7.0 x 10⁶ Pa

Bulk modulus of copper, B = 140 x 10⁹ Pa

Bulk modulus, B = \(\frac {\frac P{△V}}{V}\) 

Where,

\(\frac {△V}{V}\) = Volumetric strain

△V = Change in volume

V = Original volume

△V = \(\frac {pV}B\)

Original volume of the cube, V = l³

△V = \(\frac {pl^3}B\)

= \(\frac {7\times 10^6\times (0.1)^3}{140\times10^9}\) 

= 5 x 10^-8 m³

= 5 x 10^-2 m^-3

Therefore, the volume contraction of the solid copper cube is 5 × 10^–2 cm^–3.

Answer 4

16. How much should the pressure on a litre of water be changed to compress it by 0.10%? 

Solution:

 Volume of water, V = 1 L 

It is given that water is to be compressed by 0.10%.

∴ Fractional change, \(\frac {△V}{V}\) = \(\frac {0.1}{100\times1}= 10^{-3}\) 

Bulk modulus, B = \(\frac {\frac P{△V}}{V}\)

p = B x \(\frac {△V}{V}\) 

Bulk modulus of water, B = 2.2 x 10⁹ Nm^-2

p = 2.2 x 10⁹ x 10^-3

= 2.2 x 10⁶ Nm^-2

Therefore, the pressure on water should be 2.2 ×10⁶ Nm^–2.

17.  Anvils made of single crystals of diamond, with the shape as shown in Figure, are used to investigate behaviour of materials under very high pressures. Flat faces at the narrow end of the anvil have a diameter of 0.50 mm, and the wide ends are subjected to a compressional force of 50,000 N. What is the pressure at the tip of the anvil?

Solution:

Diameter of the cones at the narrow ends, d = 0.50 mm = 0.5 × 10–3 m

Radius, r = \(\frac d2\) = 0.25 x 10^-3m

Compressional force, F = 50000 N 

Pressure at the tip of the anvil:

= 2.55 x 10¹¹ Pa

Therefore, the pressure at the tip of the anvil is 2.55 × 10¹¹ Pa.

18. A rod of length 1.05 m having negligible mass is supported at its ends by two wires of steel (wire A) and aluminium (wire B) of equal lengths as shown in Figure. The cross sectional areas of wires A and B are 1.0 mm² and 2.0 mm² , respectively. At what point along the rod should a mass m be suspended in order to produce (a) equal stresses and (b) equal strains in both steel and aluminium wires.

Solution:

(a) 0.7 m from the steel-wire end 0.432 m from the steel-wire end 

Cross-sectional area of wire A, a₁ = 1.0 mm² = 1.0 × 10^–6 m² 

Cross-sectional area of wire B, a₂ = 2.0 mm² = 2.0 × 10^–6 m² 

Young’s modulus for steel, Y₁ = 2 × 10¹¹ Nm^–2 

Young’s modulus for aluminium, Y₂ = 7.0 ×1010 Nm^–2 

Let a small mass m be suspended to the rod at a distance y from the end where wire A is attached.

Stress in the wire = \(\frac {Force}{Area} = \frac Fa\)

If the two wires have equal stresses, then:

\(\frac {F_1}{a_1} = \frac {F_2}{a_2} \)

Where,

F₁ = Force exerted on the steel wire 

F₂ = Force exerted on the aluminum wire

The situation is shown in the following figure.

Taking torque about the point of suspension, we have:

Using equations (i) and (ii), we can write:

\(\frac {(1.05-y)}{y} = \frac 12\) 

2(1.05-y) = y

2.1 - 2y = y

3y = 2.1

∴ y = 0.7m

In order to produce an equal stress in the two wires, the mass should be suspended at a distance of 0.7 m from the end where wire A is attached.

Young's modulus = \(\frac {Stress}{Strain}\) 

Strain =  \(\frac {Stress}{Young's\, modulus} = \frac {\frac Fa}{Y}\) 

If the strain in the two wires is equal, then:

Taking torque about the point where mass m, is suspended at a distance y₁ from the side where wire A attached, we get:

F₁y₁ = F₂ (1.05 – y₁)

Using equations (iii) and (iv), we get:

 \(\frac {(1.05-y_1)}{y_1} = \frac {10}7\) 

7(1.05-y₁) = 10y₁

17 y₁ = 7.35

∴ y₁ = 0.432 m

In order to produce an equal strain in the two wires, the mass should be suspended at a distance of 0.432 m from the end where wire A is attached.

19. A mild steel wire of length 1.0 m and cross-sectional area 0.50 × 10^–2 cm² is stretched, well within its elastic limit, horizontally between two pillars. A mass of 100 g is suspended from the mid-point of the wire. Calculate the depression at the midpoint.

Solution:

Length of the steel wire = 1.0 m

Area of cross-section, A = 0.50 x 10^-2 cm² = 0.50 x 10^-6 m²

A mass 100g is suspended from its midpoint

m = 100g = 0.1 kg

Hence, the wire dips, as shown in the given figure.

Original length = XZ 

Depression = l 

The length after mass m, is attached to the wire = XO + OZ 

Increase in the length of the wire: 

Δl = (XO + OZ) – XZ 

Where,

Expanding and neglecting higher terms, we get:

Δl = \(\frac {l^2}{0.5}\)

Strain = \(\frac {Increase \, in\, length}{Original\, length}\) 

Let T be the tension in the wire. 

∴ mg = 2T cosθ 

Using the figure, it can be written as:

Expanding the expression and eliminating the higher terms:

Young's modulus = \(\frac {Stress}{Strain}\) 

Young’s modulus of steel, Y = 2 x 10¹¹ Pa

= 0.0106 m

Hence, the depression at the midpoint is 0.0106 m.

Answer 5

20. Two strips of metal are riveted together at their ends by four rivets, each of diameter 6.0 mm. What is the maximum tension that can be exerted by the riveted strip if the shearing stress on the rivet is not to exceed 6.9 × 10⁷ Pa? Assume that each rivet is to carry one quarter of the load.

Solution:

Diameter of the metal strip, d = 6.0 mm = 6.0 × 10^–3 m

Radius, r = \(\frac d2\) = 3.0 x 10^-3m

Maximum shearing stress = 6.9 x 10⁷ Pa

Maximum stress = \(\frac {Maximum\, load \,or\, force}{Area}\) 

Maximum force = Maximum stress x Area

= 6.9 x 10⁷ x π x (r)²

= 6.9 x 10⁷ x π x (3 x 10^-3)²

= 1949.94 N

Each rivet carries one quarter of the load 

∴ Maximum tension on each rivet = 4 x 1949.94 = 7799.76 N

21. The Marina trench is located in the Pacific Ocean, and at one place it is nearly eleven km beneath the surface of water. The water pressure at the bottom of the trench is about 1.1 × 10⁸ Pa. A steel ball of initial volume 0.32 m³ is dropped into the ocean and falls to the bottom of the trench. What is the change in the volume of the ball when it reaches to the bottom?

Solution:

Water pressure at the bottom, p = 1.1 x 10⁸ Pa

Initial volume of the steel ball, V = 0.32 m³

Bulk modulus of steel, B = 1.6 x 10¹¹ Nm^-2

The ball falls at the bottom of the Pacific Ocean, which is 11 km beneath the surface.

Let the change in the volume of the ball on reaching the bottom of the trench be △V.

Bulk modulus, B = \(\frac {\frac P{△V}}{V}\)

△V = \(\frac {B}{pV}\) 

= \(\frac {1.1 \times 10^8 \times 0.32}{1.6\times 10^{11}}\)

= 2.2 x 10^-4 m³

Therefore, the change in volume of the ball on reaching the bottom of the trench is 2.2 × 10^-4 m³.