Given data,

Diameter of both the wires, d = 0.25 cm

Hence, radius of both the wires = r = d/2

⇒ r = 0.25/2 cm

⇒ r = 0.125 cm.

Length of the steel wire, L_s = 1.5 m

Length of the brass wire, L_b = 1.0 m

From the given figure, the total force exerted on the steel wire:

F_s = (4 kg + 6 kg) × 9.8 ms^-2

Here, 9.8 ms^-2 is the acceleration due to gravity which acts along with the force attached to the wires.

⇒ F_s = 10 × 9.8 = 98 N.

Young’s modulus for steel:

Y_s = ………………… (1)

Where,

= Change in the length of the steel wire.

= Area of cross-section of the steel wire = πr²

⇒ A_s = π×(0.125× 10^-2)² m²

Young’s modulus for steel from standard table is, 2.0× 10¹¹ Pa

Substituting the value is (1)

2.0× 10¹¹ Pa =

ΔL_s =

⇒ ΔL_s = 1.49 × 10^-4 m

Hence, elongation of the steel wire is 1.49 × 10^-4 m.

From the given figure, the total force exerted on the brass wire:

F_b = 6 kg × 9.8 ms^-2

Here, 9.8 ms^-2 is the acceleration due to gravity which acts along with the force attached to the wires.

⇒ F_b = 6 kg × 9.8 ms^-2 = 58.8 N.

Young’s modulus for steel:

Y_b = ………………… (1)

Where,

= Change in the length of the brass wire.

= Area of cross-section of the brass wire = πr²

⇒ A_b = π×(0.125× 10^-2)² m²

Young’s modulus for brass from standard table is, 0.91× 10¹¹ Pa

Substituting the value is (1)

0.91× 10¹¹ Pa =

=

⇒ ΔL_b = 1.3 × 10^-4 m

Hence, elongation of the steel wire is 1.3 × 10^-4 m.