18: Calculation of Magnetic Quantities from Currents

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18.1: Introduction
This chapter provides methods in detail for calculating magnetic fields and forces. It also covers some additional applications of magnetism not covered in Part 1.
18.2: Magnetic Field due to a Thin Straight Wire
How does the shape of wires carrying current affect the shape of the magnetic field created? We know that a current loop created a magnetic field similar to that of a bar magnet, but what about a straight wire? We can use the Biot-Savart law to answer all of these questions, including determining the magnetic field of a long straight wire.
18.3: Magnetic Field of a Current Loop
We can use the Biot-Savart law to find the magnetic field due to a current. We first consider arbitrary segments on opposite sides of the loop to qualitatively show by the vector results that the net magnetic field direction is along the central axis from the loop. From there, we can use the Biot-Savart law to derive the expression for magnetic field.
18.4: Magnetic Field using Ampère’s Law
A fundamental property of a static magnetic field is that, unlike an electrostatic field, it is not conservative. A conservative field is one that does the same amount of work on a particle moving between two different points regardless of the path chosen. Magnetic fields do not have such a property. Instead, there is a relationship between the magnetic field and its source, electric current. It is expressed in terms of the line integral B and is known as Ampère’s law.
18.5: Magnetic Field of Solenoids and Toroids
Two of the most common and useful electromagnetic devices are called solenoids and toroids. In one form or another, they are part of numerous instruments, both large and small. In this section, we examine the magnetic field typical of these devices.
18.6: Magnetic Force between Two Parallel Currents
You might expect that two current-carrying wires generate significant forces between them, since ordinary currents produce magnetic fields and these fields exert significant forces on ordinary currents. But you might not expect that the force between wires is used to define the ampere. It might also surprise you to learn that this force has something to do with why large circuit breakers burn up when they attempt to interrupt large currents.
18.7: (edit) Magnetic Force and Torque on a Current Loop - Motors and Meters
Motors are the most common application of magnetic force on current-carrying wires. Motors contain loops of wire in a magnetic field. When current is passed through the loops, the magnetic field exerts torque on the loops, which rotates a shaft. Electrical energy is converted into mechanical work in the process.
18.8: Magnetic Forces in a Conductor - The Hall Effect
E.H. Hall devised an experiment that can be used to identify the sign of the predominant charge carriers in a conducting material. From a historical perspective, this experiment was the first to demonstrate that the charge carriers in most metals are negative.
18.9: More Applications of Magnetism
Crossed (perpendicular) electric and magnetic fields act as a velocity filter, giving equal and opposite forces on any charge with velocity perpendicular to the fields and of magnitude \[v = \frac{E}{B}.\]
18.10: Superconductors
Transmission of electric power produces line losses. These line losses exist whether the power is generated from conventional power plants (using coal, oil, or gas), nuclear plants, solar plants, hydroelectric plants, or wind farms. These losses can be reduced, but not eliminated, by transmitting using a higher voltage. It would be wonderful if these line losses could be eliminated, but that would require transmission lines that have zero resistance.
18.11: Conclusion
18.12: Magnetic Forces and Fields (Summary)
18.13: Sources of Magnetic Fields (Summary)
18.14: Current and Resistance (Summary)
18.15: Magnetic Forces and Fields (Exercise)
18.16: Sources of Magnetic Fields (Exercise)
18.17: Magnetic Forces and Fields (Answers)
18.18: Sources of Magnetic Fields (Answers)

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