Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 24 Electromagnetic waves. So far you have learned 1.Coulomb’s Law – Ch. 19 2.There are no Magnetic Monopoles – Ch. 22.1 3.Faraday’s Law of Induction.

Published byAnnabel Curtis Modified over 9 years ago

Similar presentations

Presentation on theme: "Chapter 24 Electromagnetic waves. So far you have learned 1.Coulomb’s Law – Ch. 19 2.There are no Magnetic Monopoles – Ch. 22.1 3.Faraday’s Law of Induction."— Presentation transcript:

1 Chapter 24 Electromagnetic waves

2 So far you have learned 1.Coulomb’s Law – Ch. 19 2.There are no Magnetic Monopoles – Ch. 22.1 3.Faraday’s Law of Induction – Ch. 23 4.Ampere’s Circuital Law – Ch. 22.9 Each law is empirical and Faraday’s is the most remarkable of these.

3 Faraday’s Law of Induction is: The EMF in a circuit is equal to the 1.Line integral of the magnetic field. 2.Surface integral of the curl of the magnetic field. 3.Rate of change of the magnetic flux enclosed by the circuit 4.Square of the hypotenuse of the current. 5.Inverse of the distance squared.

4 Faraday’s Law of Induction (Chapter 23) implies an electric field is produced by a changing magnetic field. EB Long solenoid with changing B. Imagine a highly resistive loop of wire in a changing magnetic field….

5 Ampere’s circuital law (Chapter 22.9) is not correct for rapidly varying currents.

6 Something is rotten… Remember my “law”? For S 1 : get I on the right But for S 2 : get zero on the right Apply it to this case… I is the current that crosses a surface bound by curve P

7 Something is rotten…

8 I can fix this! No current goes through S 2, but an electric field does! For S 1 : get I on the right and E Gauss’s law Almost all electric flux goes through S 2

9 E Take d/dt of this equation Gives dQ/dt across S 1 Gives dQ/dt across S 2 S1S1 S2S2

10 E I propose to replace I in Ampere’s law with: The Ampere-Maxwell Law: The ordinary electrical currentThe displacement current

11 Origin of the term “Displacement Current” Dielectric material -Q+Q II The dielectric material is polarized by the displacement of bound charges, and there is a “displacement current” associated with the movement of the bound charges.

12 Origin of the term “Displacement Current” Vacuum -Q+Q II The amazing experimental fact is that there is a “displacement current” associated with the [polarization of the] vacuum! The conclusion is that A magnetic field is produced by a changing electric field.

13 Direct observation of the “Displacement Current” is not so easy. In fact only conduction currents contribute to the magnetic field at low frequencies, so the first test by Hertz was really the best test of the Ampere-Maxwell law: the existence of Hertzian waves.

14 My equations: And the Lorentz force from E and B on A charges q:

15 describe all electric and magnetic phenomena and LIGHT

16 Maxwell’s equations 1.May be derived from pure thought. 2.Are mathematical descriptions of empirical fact. 3.Are irrelevant to modern physics.

17 Electromagnetic waves If we look at Maxwell’s eqns where there are no charges or currents - after a bit of math we will get… Units of 1/speed 2

18 Suppose we start with a sine wave electric field in the x direction traveling in the z direction: The Ampere-Maxwell law says

19 Then the Faraday law of induction says This can only be true if

20 The speed of the waves is Units of 1/speed 2 Light is an electromagentic wave It is described by Maxwell’s equations Electricity, magnetism and optics are different aspects of the same theory

21 This is in the vacuum. In a medium of dielectric constant  and magnetic permeability  the speed of light is

Download ppt "Chapter 24 Electromagnetic waves. So far you have learned 1.Coulomb’s Law – Ch. 19 2.There are no Magnetic Monopoles – Ch. 22.1 3.Faraday’s Law of Induction."

Similar presentations

Energy stored in Magnetic Fields

Energy stored in Magnetic Fields
Lecture 5: Time-varying EM Fields

Lecture 5: Time-varying EM Fields
PH0101 UNIT 2 LECTURE 2 Biot Savart law Ampere’s circuital law

PH0101 UNIT 2 LECTURE 2 Biot Savart law Ampere’s circuital law
Chapter 29 Faraday’s Law. Electromagnetic Induction In the middle part of the nineteenth century Michael Faraday formulated his law of induction. It had.

Chapter 29 Faraday’s Law. Electromagnetic Induction In the middle part of the nineteenth century Michael Faraday formulated his law of induction. It had.
MAXWELL’S EQUATIONS 1. 2 Maxwell’s Equations in differential form.

MAXWELL’S EQUATIONS 1. 2 Maxwell’s Equations in differential form.
EMLAB 1 Introduction to electromagnetics. EMLAB 2 Electromagnetic phenomena The globe lights up due to the work done by electric current (moving charges).

EMLAB 1 Introduction to electromagnetics. EMLAB 2 Electromagnetic phenomena The globe lights up due to the work done by electric current (moving charges).
Maxwell’s Equations The two Gauss’s laws are symmetrical, apart from the absence of the term for magnetic monopoles in Gauss’s law for magnetism Faraday’s.

Maxwell’s Equations The two Gauss’s laws are symmetrical, apart from the absence of the term for magnetic monopoles in Gauss’s law for magnetism Faraday’s.
AP Physics C Montwood High School R. Casao

AP Physics C Montwood High School R. Casao
General form of Faraday’s Law

General form of Faraday’s Law
-Generators -Motors -Eddy Currents -Maxwell’s Four Equations AP Physics C Mrs. Coyle.

-Generators -Motors -Eddy Currents -Maxwell’s Four Equations AP Physics C Mrs. Coyle.
Electromagnetism week 9 Physical Systems, Tuesday 6.Mar. 2007, EJZ Waves and wave equations Electromagnetism & Maxwell’s eqns Derive EM wave equation and.

Electromagnetism week 9 Physical Systems, Tuesday 6.Mar. 2007, EJZ Waves and wave equations Electromagnetism & Maxwell’s eqns Derive EM wave equation and.
Ch 32 Maxwell’s Equations 1)Gauss’ Law for Electrostatics 2)Gauss’ Law for Magnetostatic 3)Faraday's Law 4)Maxwell-Ampere Law They predict that light is.

Ch 32 Maxwell’s Equations 1)Gauss’ Law for Electrostatics 2)Gauss’ Law for Magnetostatic 3)Faraday's Law 4)Maxwell-Ampere Law They predict that light is.
Electromagnetic Waves

Electromagnetic Waves
Chapter 31 Faraday’s Law.

Chapter 31 Faraday’s Law.
Electromagnetic Induction We address now the question: what is the physics behind electric power generation? Let’s follow the experimental path to Faraday’s.

Electromagnetic Induction We address now the question: what is the physics behind electric power generation? Let’s follow the experimental path to Faraday’s.
Magnetostatics Magnetostatics is the branch of electromagnetics dealing with the effects of electric charges in steady motion (i.e, steady current or DC).

Magnetostatics Magnetostatics is the branch of electromagnetics dealing with the effects of electric charges in steady motion (i.e, steady current or DC).
8/5/08Lecture 2 Part 21 Maxwell’s Equations of the Electromagnetic Field Theory Gauss’s Law – charge makes an electric field The magnetic field is solenoidal.

8/5/08Lecture 2 Part 21 Maxwell’s Equations of the Electromagnetic Field Theory Gauss’s Law – charge makes an electric field The magnetic field is solenoidal.
Electromagnetism Giancoli Ch Physics of Astronomy, winter week 7

Electromagnetism Giancoli Ch Physics of Astronomy, winter week 7
The Electric and Magnetic fields Maxwell’s equations in free space References: Feynman, Lectures on Physics II Davis & Snyder, Vector Analysis.

The Electric and Magnetic fields Maxwell’s equations in free space References: Feynman, Lectures on Physics II Davis & Snyder, Vector Analysis.
Faraday’s law cannot be derived from the other fundamental principles we have studied Formal version of Faraday’s law: Sign: given by right hand rule Faraday’s.

Faraday’s law cannot be derived from the other fundamental principles we have studied Formal version of Faraday’s law: Sign: given by right hand rule Faraday’s.

Similar presentations

Ads by Google