Final answer:
The force required to stretch resilin from a relaxed length of 1.00 cm to a stretched length of 3.68 cm, given a Young's modulus of 1.70 MPa and a cross-sectional area of 1.00 mm², is approximately 4.556 N.
Step-by-step explanation:
The question pertains to the force needed to extend a piece of resilin from its relaxed state to a stretched state. This is a practical application of Hooke's Law, which describes the behavior of springs and elastic materials. The Young's modulus (E) given is essential to relate the stress and strain in a linear elastic material like resilin.
For a piece of resilin, the stress (σ) is the force applied (F) divided by the cross-sectional area (A), and the strain (ε) is the fractional change in length (ΔL over L0). The Young's modulus (E) relates the stress and strain by σ = Eε. To find the force needed, we rearrange the formula to F = EεA.
Given:
- Young's modulus (E) = 1.70 MPa = 1.70 × 106 Pa
- Relaxed length (L0) = 1.00 cm
- Stretched length = 3.68 cm
- Change in length (ΔL) = Stretched length - Relaxed length = 2.68 cm
- Cross-sectional area (A) = 1.00 mm² = 1.00 × 10-6 m²
Calculating the strain, ε = ΔL/L0 = 2.68 cm / 1.00 cm = 2.68.
Applying the values:
F = (1.70 × 106 Pa)(2.68)(1.00 × 10-6 m²)
Therefore, the force required to extend the resilin to 3.68 cm is:
F = 4.556 N (approximately)