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Check Your Understanding Current flows through the inductor in [link] from B to A instead of from A to B as shown. Is the current increasing or decreasing in order to produce the emf given in diagram (a)? In diagram (b)?

a. decreasing; b. increasing; Since the current flows in the opposite direction of the diagram, in order to get a positive emf on the left-hand side of diagram (a), we need to decrease the current to the left, which creates a reinforced emf where the positive end is on the left-hand side. To get a positive emf on the right-hand side of diagram (b), we need to increase the current to the left, which creates a reinforced emf where the positive end is on the right-hand side.

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Check Your Understanding A changing current induces an emf of 10 V across a 0.25-H inductor. What is the rate at which the current is changing?

40 A/s

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A good approach for calculating the self-inductance of an inductor consists of the following steps:

Problem-solving strategy: self-inductance

  1. Assume a current I is flowing through the inductor.
  2. Determine the magnetic field B produced by the current. If there is appropriate symmetry, you may be able to do this with Ampère’s law.
  3. Obtain the magnetic flux, Φ m .
  4. With the flux known, the self-inductance can be found from [link] , L = N Φ m / I .

To demonstrate this procedure, we now calculate the self-inductances of two inductors.

Cylindrical solenoid

Consider a long, cylindrical solenoid with length l , cross-sectional area A , and N turns of wire. We assume that the length of the solenoid is so much larger than its diameter that we can take the magnetic field to be B = μ 0 n I throughout the interior of the solenoid, that is, we ignore end effects in the solenoid. With a current I flowing through the coils, the magnetic field produced within the solenoid is

B = μ 0 ( N l ) I ,

so the magnetic flux through one turn is

Φ m = B A = μ 0 N A l I .

Using [link] , we find for the self-inductance of the solenoid,

L solenoid = N Φ m I = μ 0 N 2 A l .

If n = N / l is the number of turns per unit length of the solenoid, we may write [link] as

L = μ 0 ( N l ) 2 A l = μ 0 n 2 A l = μ 0 n 2 ( V ) ,

where V = A l is the volume of the solenoid. Notice that the self-inductance of a long solenoid depends only on its physical properties (such as the number of turns of wire per unit length and the volume), and not on the magnetic field or the current. This is true for inductors in general.

Rectangular toroid

A toroid with a rectangular cross-section is shown in [link] . The inner and outer radii of the toroid are R 1 and R 2 , and h is the height of the toroid. Applying Ampère’s law in the same manner as we did in [link] for a toroid with a circular cross-section, we find the magnetic field inside a rectangular toroid is also given by

B = μ 0 N I 2 π r ,

where r is the distance from the central axis of the toroid. Because the field changes within the toroid, we must calculate the flux by integrating over the toroid’s cross-section. Using the infinitesimal cross-sectional area element d a = h d r shown in [link] , we obtain

Φ m = B d a = R 1 R 2 ( μ 0 N I 2 π r ) ( h d r ) = μ 0 N h I 2 π ln R 2 R 1 .
Figure shows the cross section of a toroid. The inner radius of the ring is R1 and the outer radius is R2. The height of the rectangular cross section is h. A small section of thickness dr is located at the center of the rectangular cross section. This is at a distance r from the center of the ring. The area within the rectangular cross section with thickness dr and height h is highlighted and labeled da. Field lines and current i flowing through the toroid are shown.
Calculating the self-inductance of a rectangular toroid.

Now from [link] , we obtain for the self-inductance of a rectangular toroid

Practice Key Terms 2

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Source:  OpenStax, University physics volume 2. OpenStax CNX. Oct 06, 2016 Download for free at http://cnx.org/content/col12074/1.3
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