Elastic Properties of solids
NIOS · Class 12 · Physics
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A steel wire of length 4 m and cross-sectional area 3.14 × 10⁻⁶ m² is stretched by a force of 62.8 N. If Young's modulus of steel is 2 × 10¹¹ N m⁻², what is the elongation produced in the wire?
A solid rubber ball is taken to the bottom of a lake 360 m deep. The density of lake water is 10³ kg m⁻³ and g = 10 m s⁻². If the volume of the ball decreases by 0.0012%, what is the bulk modulus of rubber?
A metal cube of side 20 cm is subjected to a shearing stress of 10⁴ N m⁻². The top face is displaced by 0.01 cm with respect to the bottom face. What is the modulus of rigidity of the metal?
A copper wire of length 5 m and diameter 1 mm is stretched by a 10 kg load. If Young's modulus Y = 1.1 × 10¹¹ N m⁻² and Poisson's ratio σ = 0.25, what is the lateral strain produced in the wire? (g = 9.8 m s⁻²)
Sample Questions
In the stress-strain curve of a metallic wire, the wire is loaded beyond the elastic limit (point B) but the load is then gradually removed. Which of the following correctly describes what happens?
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The wire follows a dotted path parallel to OA back to zero stress but retains a permanent set (residual strain).
Step 1: Beyond the elastic limit, the wire behaves plastically — permanent deformation occurs in the crystal structure. Step 2: When load is removed, the wire does recover partially (elastic recovery), following a line parallel to the initial OA region of the curve. Step 3: However, it does NOT return to zero strain; a residual strain called 'permanent set' remains. Step 4: Option A is wrong because complete recovery is only possible within the elastic limit. Option C is wrong because the wire breaks only at the fracture point F, which is well beyond B. Option D incorrectly suggests higher str
What is the maximum length of a steel wire that can be suspended vertically without breaking under its own weight? Given: breaking stress = 4.0 × 10⁸ N m⁻², density of steel = 7.9 × 10³ kg m⁻³, g = 9.8 m s⁻².
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5.17 km
Step 1: The weight of a wire of cross-sectional area A and length ℓ is W = Aℓρg. Step 2: Stress at the top due to its own weight = W/A = ℓρg. Step 3: At maximum length, this equals breaking stress: ℓ_max = Breaking stress / (ρg). Step 4: ℓ_max = (4.0 × 10⁸) / (7.9 × 10³ × 9.8) = (4.0 × 10⁸) / (7.742 × 10⁴) ≈ 5.17 × 10³ m ≈ 5.17 km. Option B results from dividing by 2ρg (factor of 2 error); option C from using ρ = 3.9 × 10³; option D from using g = 16 m/s². The key insight is that cross-sectional area cancels out, so maximum length is independent of wire thickness.
A spring of spring constant 500 N m⁻¹ is first compressed by 4 cm and then by 8 cm from its natural length. What is the ratio of elastic potential energy stored in the second case to the first case?
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4 : 1
Step 1: Elastic potential energy U = ½kx², so U ∝ x². Step 2: In case 1: x₁ = 4 cm = 0.04 m; U₁ = ½ × 500 × (0.04)² = ½ × 500 × 0.0016 = 0.4 J. Step 3: In case 2: x₂ = 8 cm = 0.08 m; U₂ = ½ × 500 × (0.08)² = ½ × 500 × 0.0064 = 1.6 J. Step 4: Ratio U₂/U₁ = 1.6/0.4 = 4:1. This can also be seen directly: since x₂ = 2x₁, U₂/U₁ = (2x₁)²/x₁² = 4. Option A (2:1) is wrong — it assumes U ∝ x (linear), not quadratic. Option C (8:1) is wrong — it assumes U ∝ x³.
Two wires, one of steel and one of rubber, have identical dimensions. Equal longitudinal forces are applied to both. Which of the following statements is physically correct and explains why steel is more elastic than rubber?
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Rubber wire stretches more for the same force; hence more stress is needed in steel for the same strain, so steel is more elastic.
Step 1: Elasticity is defined as the ability to resist deformation — a body requiring more stress to produce the same strain is more elastic. Step 2: When equal forces are applied, rubber stretches far more than steel (lower Young's modulus for rubber). Step 3: To produce the SAME strain in steel as in rubber, a much larger stress is required — this means steel's internal restoring force is much stronger. Step 4: Hence steel is more elastic. Option A is self-contradictory. Option C is factually wrong — steel stretches far less. Option D confuses 'stretchability' (large strain capability) with
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