Presentation is loading. Please wait.

Presentation is loading. Please wait.

Electricity and Magnetism

Published byΖώσιμη Ζερβός Modified over 4 years ago

Similar presentations

Presentation on theme: "Electricity and Magnetism"— Presentation transcript:

1 Electricity and Magnetism
Physics 208 Dr. Tatiana Erukhimova Lectures 29, 30

2 Current carrying wires
1820 Hans Christian Oersted Hans Christian Ørsted

3 Biot-Savart Law Infinitesimally small element of a current carrying wire produces an infinitesimally small magnetic field is called permeability of free space (Also called Ampere’s principle)

4

5 Ampere’s Law The field produced by an infinite wire

6 Problem 6 An infinitely long, hollow cylindrical wire has inner radius a and outer radius b. A current i is uniformly distributed over its cross-section. Find the magnetic field everywhere.

7 Problem 3 An infinitely long wire has 5 amps flowing in it. A rectangular loop of wire, oriented as shown in the plane of the paper, has 4 amps in it. What is the force exerted on the loop by the long wire?

8 Problem 4 Consider a very long (essentially infinite), tightly wound coil with n turns per unit length. This is called a solenoid. Assume that the lines of B are parallel to the axis of the solenoid and non-zero only inside the coil and very far away. Also assume that B is constant inside. Find B inside the solenoid if there is a current i flowing through it.

9 Induced EMF and Inductance
1830s Michael Faraday Joseph Henry

10 Faraday’s Law of Induction
The induced EMF in a closed loop equals the negative of the time rate of change of magnetic flux through the loop

11 There can be EMF produced in a number of ways:
A time varying magnetic field An area whose size is varying A time varying angle between and Any combination of the above

12

13 From Faraday’s law: a time varying flux through a circuit will induce an EMF in the circuit. If the circuit consists only of a loop of wire with one resistor, with resistance R, a current R Which way? Lenz’s Law: if a current is induced by some change, the direction of the current is such that it opposes the change.

Download ppt "Electricity and Magnetism"

Similar presentations

Energy In a Magnetic Field

Energy In a Magnetic Field
Magnetic Field due to a Current-Carrying Wire Biot-Savart Law

Magnetic Field due to a Current-Carrying Wire Biot-Savart Law
Electromagnetic Induction Inductors. Problem A metal rod of length L and mass m is free to slide, without friction, on two parallel metal tracks. The.

Electromagnetic Induction Inductors. Problem A metal rod of length L and mass m is free to slide, without friction, on two parallel metal tracks. The.
Biot-Savart Law The Field Produced by a Straight Wire.

Biot-Savart Law The Field Produced by a Straight Wire.
Induced EMF and Inductance 1830s Michael Faraday Joseph Henry.

Induced EMF and Inductance 1830s Michael Faraday Joseph Henry.
Problem 2 Find the torque about the left hand segment on the loop as a function of θ, the angle the plane makes with the horizontal plane.

Problem 2 Find the torque about the left hand segment on the loop as a function of θ, the angle the plane makes with the horizontal plane.
In the circuit below, suppose the switch has been in position A for a very long time. If it is then switched to B at t=0, find the current as a function.

In the circuit below, suppose the switch has been in position A for a very long time. If it is then switched to B at t=0, find the current as a function.
Current carrying wires 1820 Hans Christian Oersted Hans Christian Ørsted.

Current carrying wires 1820 Hans Christian Oersted Hans Christian Ørsted.
Waves can be represented by simple harmonic motion.

Waves can be represented by simple harmonic motion.
Biot-Savart Law The Field Produced by a Straight Wire.

Biot-Savart Law The Field Produced by a Straight Wire.
INDUCTANCE Plan:  Inductance  Calculating the Inductance  Inductors with Magnetic materials.

INDUCTANCE Plan:  Inductance  Calculating the Inductance  Inductors with Magnetic materials.
CHAPTER 20, SECTION 1 ELECTRICITY FROM MAGNETISM.

CHAPTER 20, SECTION 1 ELECTRICITY FROM MAGNETISM.
B due to a moving point charge where  0 = 4  x10 -7 T.m/A Biot-Savart law: B due to a current element B on the axis of a current loop B inside a solenoid.

B due to a moving point charge where  0 = 4  x10 -7 T.m/A Biot-Savart law: B due to a current element B on the axis of a current loop B inside a solenoid.
Lecture 16 Magnetism (3) History 1819 Hans Christian Oersted discovered that a compass needle was deflected by a current carrying wire Then in 1920s.

Lecture 16 Magnetism (3) History 1819 Hans Christian Oersted discovered that a compass needle was deflected by a current carrying wire Then in 1920s.
Review 1.

Review 1.
Magnetism and its applications.

Magnetism and its applications.
Faraday’s Law and Inductance. Faraday’s Law A moving magnet can exert a force on a stationary charge. Faraday’s Law of Induction Induced emf is directly.

Faraday’s Law and Inductance. Faraday’s Law A moving magnet can exert a force on a stationary charge. Faraday’s Law of Induction Induced emf is directly.
Electro- magnetic Induction Lecture 3 AP Physics.

Electro- magnetic Induction Lecture 3 AP Physics.
Chapter 20 Electromagnetic Induction. Electricity and magnetism Generators, motors, and transformers.

Chapter 20 Electromagnetic Induction. Electricity and magnetism Generators, motors, and transformers.
Magnetism Alternating-Current Circuits

Magnetism Alternating-Current Circuits

Similar presentations

Ads by Google