- 6.1P: Calculate the torque exerted on the square loop shown in Fig. 6.6, ...
- 6.2P: Starting from the Lorentz force law, in the form of Eq. 5.16, show ...
- 6.3P: Find the force of attraction between two magnetic dipoles, m1 and m...
- 6.4P: Derive Eq. 6.3. [Here’s one way to do it: Assume the dipole is an i...
- 6.5P: A uniform current density fills a slab straddling the yz plane, fro...
- 6.6P: Of the following materials, which would you expect to be paramagnet...
- 6.7P: An infinitely long circular cylinder carries a uniform magnetizatio...
- 6.8P: A long circular cylinder of radius R carries a magnetization M = wh...
- 6.9P: A short circular cylinder of radius a and length L carries a “froze...
- 6.10P: An iron rod of length L and square cross section (side a) is given ...
- 6.11P: In Sect, 6.2.1, we began with the potential of a perfect dipole (Eq...
- 6.12P: An infinitely long cylinder, of radius R, carries a “frozen-in” mag...
- 6.13P: Suppose the field inside a large piece of magnetic material is B0, ...
- 6.14P: For the bar magnet of Prob. 6.9, make careful sketches of M, B, and...
- 6.15P: ?If J1 = 0 everywhere, the curl of H vanishes (eq. 6.19), and we ca...
- 6.16P: A coaxial cable consists of two very long cylindrical tubes, separa...
- 6.17P: A current I flows down a long straight wire of radius a. If the wir...
- 6.18P: A sphere of linear magnetic material is placed in an otherwise unif...
- 6.19P: On the basis of the naïve model presented in Sect. 6.1.3, estimate ...
- 6.20P: How would you go about demagnetizing a permanent magnet (such as th...
- 6.21P: (a) Show that the energy of a magnetic dipole in a magnetic field B...
- 6.22P: In Prob. 6.4, you calculated the force on a dipole by “brute force....
- 6.23P: A familiar toy consists of donut-shaped permanent magnets (magnetiz...
- 6.25P: Notice the following parallel: Thus, the transcription D?B, E?H, P?...
- 6.26P: Compare Eqs. 2.15, 4.9, and 6.11. Notice that if ?, P, and M are un...
- 6.27P: At the interface between one linear magnetic material and another, ...
- 6.28P: A magnetic dipole m is imbedded at the center of a sphere (radius R...
- 6.29P: You are asked to referee a grant application, which proposes to det...
Solutions for Chapter 6: Magnetic Fields in Matter
Full solutions for Introduction to Electrodynamics | 4th Edition
ISBN: 9780321856562
Solutions for Chapter 6
19
3
Summary of Chapter 6: Magnetic Fields in Matter
If you ask the average person what "magnetism" is, you will probably be told about refrigerator decorations, compass needles, and the North Pole-none of which has any obvious connection with moving charges or current-carrying wires.
Chapter 6: Magnetic Fields in Matter includes 28 full step-by-step solutions. Since 28 problems in chapter 6: Magnetic Fields in Matter have been answered, more than 248436 students have viewed full step-by-step solutions from this chapter. This textbook survival guide was created for the textbook: Introduction to Electrodynamics , edition: 4. Introduction to Electrodynamics was written by and is associated to the ISBN: 9780321856562. This expansive textbook survival guide covers the following chapters and their solutions.
Key Physics Terms and definitions covered in this textbook
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parallel
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any symbol
average (indicated by a bar over a symbol—e.g., v¯ is average velocity)
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°C
Celsius degree
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°F
Fahrenheit degree