Physics Problem: Magnetic Induction in a Loop
Question:
A magnetized bullet is fired through the center of a loop of wire with radius r = 30 cm. At its peak, the average magnetic field in the plane of the loop and inside the loop is Bavg = 0.01 T. The magnetic field increases from B = 0 to B = 0.01 T and returns to B = 0 in a time interval Δt = 0.0065 sec.
Find:
- (a) The average induced emf in the loop.
- (b) The average current in the loop, given that its total resistance is R = 0.001 Ω.
- (c) The total energy dissipated in the loop.
Solution:
Step 1: Area of the Loop
Radius: r = 30 cm = 0.30 m
A = πr² = π(0.30)² ≈ 0.2827 m²
Step 2: Use Faraday’s Law to Find Average Induced EMF
Faraday’s Law:
εavg = ΔΦ / Δt = A × ΔB / Δt
εavg = (0.2827 × 0.01) / 0.0065 ≈ 0.4357 V
Step 3: Use Ohm’s Law to Find Average Current
Ohm’s Law:
Iavg = ε / R = 0.4357 / 0.001 = 435.7 A
Step 4: Total Energy Dissipated in the Loop
Use:
E = I² × R × Δt = (435.7)² × 0.001 × 0.0065 ≈ 1.234 J
✅ Final Answers:
(a) Average induced emf: 0.436 V
(b) Average current: 435.7 A
(c) Total energy dissipated: 1.23 J
(a) Average induced emf: 0.436 V
(b) Average current: 435.7 A
(c) Total energy dissipated: 1.23 J