Answered

Get comprehensive answers to your questions with the help of IDNLearn.com's community. Our platform is designed to provide accurate and comprehensive answers to any questions you may have.

A circular coil that has [tex]$N=220$[/tex] turns and a radius of [tex]$r=10.5 \, \text{cm}$[/tex] lies in a magnetic field that has a magnitude of [tex][tex]$B_0=0.0605 \, \text{T}$[/tex][/tex] directed perpendicular to the plane of the coil.

What is the magnitude of the magnetic flux [tex]$\Phi_B$[/tex] through the coil?
[tex]\[ \Phi_B = \, \square \, \text{T} \cdot \text{m}^2 \][/tex]

The magnetic field through the coil is increased steadily to [tex]0.200 \, \text{T}[/tex] over a time interval of [tex]0.480 \, \text{s}[/tex].

What is the magnitude [tex]| E |[/tex] of the emf induced in the coil during the time interval?
[tex]\[ | E | = \, \square \, \text{V} \][/tex]

Sagot :

GinnyAnsweridn
To solve this problem, we'll approach it step-by-step.

### Step 1: Calculate the Magnetic Flux through the Coil

The magnetic flux [tex]\(\Phi_B\)[/tex] through a coil is given by the formula:
[tex]\[ \Phi_B = N \cdot B \cdot A \][/tex]
where:
- [tex]\(N\)[/tex] is the number of turns in the coil,
- [tex]\(B\)[/tex] is the magnetic field strength,
- [tex]\(A\)[/tex] is the area of the coil.

Given:
- [tex]\(N = 220\)[/tex] turns,
- [tex]\(B_0 = 0.0605 \, T\)[/tex],
- Radius of the coil, [tex]\(r = 10.5 \, \text{cm} = 0.105 \, m\)[/tex].

First, we need to calculate the area [tex]\(A\)[/tex] of the circular coil:
[tex]\[ A = \pi r^2 \][/tex]
Substitute the radius:
[tex]\[ A = \pi \times (0.105 \, m)^2 \][/tex]

Next, we compute the magnetic flux [tex]\(\Phi_B\)[/tex]:
[tex]\[ \Phi_B = 220 \times 0.0605 \times \pi \times (0.105)^2 \][/tex]

The result of this calculation is:
[tex]\[ \Phi_B = 0.46100594536756356 \, T \cdot m^2 \][/tex]

### Step 2: Calculate the Induced EMF

The induced emf [tex]\(|E|\)[/tex] during a change in magnetic field is given by Faraday's Law of Induction:
[tex]\[ |E| = N \cdot \frac{\Delta B \cdot A}{\Delta t} \][/tex]
where:
- [tex]\(\Delta B\)[/tex] is the change in magnetic field,
- [tex]\(\Delta t\)[/tex] is the time interval over which the change occurs.

Given:
- Final magnetic field, [tex]\(B_0 = 0.200 \, T\)[/tex],
- Initial magnetic field, [tex]\(B_0 = 0.0605 \, T\)[/tex],
- Time interval, [tex]\(\Delta t = 0.480 \, \text{s}\)[/tex].

Calculate the change in magnetic field:
[tex]\[ \Delta B = B_0 \, \text{final} - B_0 \, \text{initial} = 0.200 - 0.0605 = 0.1395 \, T \][/tex]

Substitute all values into the emf formula:
[tex]\[ |E| = 220 \times \frac{0.1395 \times \pi \times (0.105)^2}{0.480} \][/tex]

The result of this calculation is:
[tex]\[ |E| = 2.214543022685094 \, V \][/tex]

### Summary

The magnitude of the magnetic flux [tex]\(\Phi_B\)[/tex] through the coil is:
[tex]\[ \Phi_B = 0.46100594536756356 \, T \cdot m^2 \][/tex]

The magnitude of the induced emf [tex]\(|E|\)[/tex] during the time interval is:
[tex]\[ |E| = 2.214543022685094 \, V \][/tex]
Your participation means a lot to us. Keep sharing information and solutions. This community grows thanks to the amazing contributions from members like you. Thank you for choosing IDNLearn.com for your queries. We’re here to provide accurate answers, so visit us again soon.