Electromagnetic “Discontinuities” Must Propagate at a speed.

Slides:

Advertisements

Similar presentations

Unit 1 Day 10 Electric Flux & Gauss’s Law

Advertisements

Two questions: (1) How to find the force, F on the electric charge, Q excreted by the field E and/or B? (2) How fields E and/or B can be created?

Charge distribution given Electric field Electric field givenCharge distribution Gauss rocks Carl Friedrich Gauss (1777–1855) We conclude.

Ch. 24 Electric Flux Gauss's Law

Maxwell’s Equations and Electromagnetic Waves Setting the Stage - The Displacement Current Maxwell had a crucial “leap of insight”... Will there still.

Week #3 Gauss’ Law September 7, What’s up Doc?? At this moment I do not have quiz grades unless I get them at the last minute. There was a short.

AP Physics C Montwood High School R. Casao

Maxwell’s Equations and Electromagnetic Waves

PHY 042: Electricity and Magnetism Energy of an E field Prof. Hugo Beauchemin 1.

Ch3 Quiz 1 First name ______________________ Last name ___________________ Section number ______ There is an electric field given by where E 0 is a constant.

Electricity&… Magnetism Review of Coulomb`s Force,Magnetic Fields and Magnetic Force Lecture 22 Monday: 5 April 2004.

Physics 262 Website: Exams: 7 midterms, scantron but not multiple choice Drop lowest.

Lecture 19 Exam II Average: Lecture 19 Today Brief review of Electrostatics (I) 1.Maxwell equations 2.Charge and current distributions.

All the fish in the river are dead, so they float with the current. The opening on the net is a flat surface of area A.

Quiz 2 Key SP212. Given: A positive point charge (+q) and a negative point charge (-q), are located at the opposite corners of a square of side length.

P W15D2 Poynting Vector and EM Waves Radiation Pressure Final Exam Review.

Hw: All Chapter 4 problems and exercises Chapter 5: Pr. 1-4; Ex. 1,2 Reading: Chapter 4.

Steps to Applying Gauss’ Law

Chapter 22 Gauss’s Law. Charles Allison © Motion of a Charged Particle in an Electric Field The force on an object of charge q in an electric.

& Electromagnetic Waves.  equivalent to Coulomb’s law.

Jaypee Institute of Information Technology University, Jaypee Institute of Information Technology University,Noida Department of Physics and materials.

AC Circuits & Phasors. We want to understand RLC circuits driven with a sinusoidal emf. First: engineers characterize the amplitude of a sinusoidal emf.

Copyright © 2009 Pearson Education, Inc. Chapter 31 Maxwell’s Equations and Electromagnetic Waves.

Copyright © 2009 Pearson Education, Inc. Chapter 34 Electromagnetic Waves.

Electromagnetic Force

Electrostatic fields Sandra Cruz-Pol, Ph. D. INEL 4151 ch 4 ECE UPRM Mayagüez, PR.

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

Objective 5 MOTION & FORCES. Have this on your desk for EVERY question involving math. FORMULAS Constants & Conversions Ruler EVERY FORMULA YOU NEED IS.

Ch. 22 in the book by Giancoli

Lesson 10 The Fields of Accelerating Charges. Class 29 Today we will: learn about threads and stubs of accelerating point charges. learn that accelerating.

Applied Electricity and Magnetism

Electromagnetic Waves. James Clerk Maxwell Scottish theoretical physicist Famous for the Maxwell- Boltzman Distribution and Maxwell’s Equations.

Few examples on calculating the electric flux

I have decided on a change in the grading policy

Electric Field Define electric field, which is independent of the test charge, q, and depends only on position in space: dipole One is > 0, the other

Gauss’s Law Electric Flux Gauss’s Law Examples. Gauss’s Law What’s in the box ??

Phys. 122: Thursday, 01 Oct. HW 4 returned: please pick up yours in front. Mast. Phys.: Assign. 4 due this evening. Assign. 5 due in one week. Written.

Waves from the Sun Electromagnetic Wave Electric field – The electric field E at a point is defined as the force per unit charge experienced by a small.

Lecture 4-1 At a point P on axis: At a point P off axis: At point P on axis of ring: ds.

1 Discussion about the mid-term 4. A high voltage generator is made of a metal sphere with a radius of 6 cm sits on an insulating post. A wire connects.

Gauss’s Law for the magnetic field is a statement of the fact that electric charge has no analog in magnetism. That is, there is no such thing as a magnetic.

Unit 4 Day 11 – Gauss’s Law for Magnetism

Chapter 24 Classical Theory of Electromagnetic Radiation.

Maxwell’s Equations. Four equations, known as Maxwell’s equations, are regarded as the basis of all electrical and magnetic phenomena. These equations.

Last Time Faraday's Law Inductance and RL (RLC) circuit.

Lecture 3-1 Electric Field Define electric field, which is independent of the test charge, q, and depends only on position in space: dipole One is > 0,

Flux and Gauss’s Law Spring Last Time: Definition – Sort of – Electric Field Lines DIPOLE FIELD LINK CHARGE.

PHYSICS 272 Electric & Magnetic Interactions

me if you want clicker points

Classical Theory of Electromagnetic Radiation

Electromagnetic Radiation

General Physics (PHY 2140) Lecture 4 Electrostatics

Physics 121 Lecture Summaries

Review Physics /10/2018 Lecture XXIV.

Gauss’s Law Electric Flux Gauss’s Law Examples.

Trivia Question James Clerk Maxwell ( ) was famous for showing that electric and magnetic fields travel through space at the speed of light. Which.

Maxwell’s Equations and Electromagnetic Waves

Chapter 23: Electromagnetic Waves

Magnetic Fields Gauss’s Law vs. Ampere’s Law Ampere’s Law

Effects of moving charges

Natural Optics KM Geise Ampère’s Law.

Physics 16/21 Electricity & magnetism

Electrostatic Boundary Value Problems Ref: Elements of Electromagnetics by Matthew N. O. Sadiku.

Lattice (bounce) diagram

Is charge moving?.

Maxwell’s Equations (so far…)

Maxwell’s Equations and Electromagnetic Waves

Ch. 23 Electric Flux Gauss's Law

Applying Gauss’s Law Gauss’s law is useful only when the electric field is constant on a given surface 1. Select Gauss surface In this case a cylindrical.

Presentation transcript:

Electromagnetic “Discontinuities” Must Propagate at a speed

Our wavefront satisfies both “Gauss’s laws” because there is no enclosed charge or current, and fields on opposite sides of the box are the same.

There is a changing B flux as the wavefront moves by. This changing flux must be equal to the line integral of the E field. Only the back edge (gh) contributes to this line integral.

There is a changing E flux also. This gives another reqd relation between E and B.

Accelerating Charges Radiate

Accelerating Charges Radiate

Coulomb’s law can’t describe the “kinked” E field. We got it from connecting field lines + geometry. However, we do get the kinked field if we consider the “potential”. “Potential” depends only on where the charge was and how fast it was moving a time r/c ago. (In other words, we have to account for the light travel time.) (we will need to do better than just the scalar electric potential, though)

But what’s it good for? Demos

Quiz: What are you doing this summer (3 pts for any answer): A] Maybe a physics problem a week or so, just to stay in top mental condition B] I won’t pick up a physics book C] I will use my expertise from Physics 161 to re- animate dead tissue.