Magnetic Force on Moving Charged Particles.

Slides:

Advertisements

Similar presentations

Gauss’ Law AP Physics C.

Advertisements

Unit 1 Day 10 Electric Flux & Gauss’s Law

Lecture Set 3 Gauss’s Law

Gauss’s law and its applications

Today’s agenda: Magnetic Fields. You must understand the similarities and differences between electric fields and field lines, and magnetic fields and.

MAXWELL’S EQUATIONS 1. 2 Maxwell’s Equations in differential form.

1 Chapter Flux Number of objects passing through a surface.

Chapter 22 Gauss’s Law Electric charge and flux (sec & .3)

Physics for Scientists and Engineers II, Summer Semester 2009 Lecture 2: May 20 th 2009 Physics for Scientists and Engineers II.

Chapter 22 Gauss’s Law Electric charge and flux (sec &.3) Gauss’s Law (sec &.5) Charges on conductors(sec. 22.6) C 2012 J. Becker.

Magnetic Flux AP Physics C Montwood High School R. Casao.

Gauss’ Law. Class Objectives Introduce the idea of the Gauss’ law as another method to calculate the electric field. Understand that the previous method.

Why Study Electromagnetics? What is Electromagnetics?

Today’s agenda: Magnetic Fields. You must understand the similarities and differences between electric fields and field lines, and magnetic fields and.

ENE 325 Electromagnetic Fields and Waves Lecture 3 Gauss’s law and applications, Divergence, and Point Form of Gauss’s law 1.

Lecture 2 The Electric Field. Chapter 15.4  15.9 Outline The Concept of an Electric Field Electric Field Lines Electrostatic Equilibrium Electric Flux.

Chapter 24 Gauss’s Law. Intro Gauss’s Law is an alternative method for determining electric fields. While it stem’s from Coulomb’s law, Gauss’s law is.

Today’s agenda: Magnetic Fields. You must understand the similarities and differences between electric fields and field lines, and magnetic fields and.

Announcements Contact me by the end of the Wednesday’s lecture if you have special circumstances different than for exam 1.  Exam 2 is one week from.

Physics 212 Lecture 3, Slide 1 Physics 212 Lecture 3 Today's Concepts: Electric Flux and Field Lines Gauss’s Law.

Lecture 9 *Definition and properties of magnetic field. *Differences between electric and magnetic force. *Magnetic flux.

Unit 4 Day 11 – Gauss’s Law for Magnetism

3/21/20161 ELECTRICITY AND MAGNETISM Phy 220 Chapter2: Gauss’s Law.

Gauss’ Law Chapter 23. Electric field vectors and field lines pierce an imaginary, spherical Gaussian surface that encloses a particle with charge +Q.

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

A dipole in an external electric field.

Chapter 22 Gauss’s Law Electric charge and flux (sec & .3)

Magnetic Force on Moving Charged Particles.

ELEC 3105 Lecture 2 ELECTRIC FIELD LINES …...

Magnetic Force on Moving Charged Particles.

A dipole in an external electric field.

Induced Electric Fields.

ACTIVE LEARNING ASSIGNMENT Engineering Electromegnetics ( )

Gauss’s Law Chapter 24.

Gauss’s Law Gauss’s law uses symmetry to simplify electric field calculations. Gauss’s law also gives us insight into how electric charge distributes itself.

Gauss’s Law ENROLL NO Basic Concepts Electric Flux

Lecture 2 : Electric charges and fields

Electric Flux & Gauss Law

Biot-Savart Law.

Magnetic Force on Moving Charged Particles.

Magnetic Force on Moving Charged Particles.

A dipole in an external electric field.

A dipole in an external electric field.

How does electric flux differ from the electric field?

Using Symmetry to Solve really complex vector calculus. . .

Flux and Gauss’s Law Spring 2009.

Flux Capacitor (Operational)

TOPIC 3 Gauss’s Law.

Electric Fields Electric Flux

A dipole in an external electric field.

Gauss’ Law AP Physics C.

Physics 122B Electricity and Magnetism

Gauss’s Law Chapter 24.

Chapter 23 Gauss’s Law.

Question for the day Can the magnitude of the electric charge be calculated from the strength of the electric field it creates?

PHYS 1902: 2018 Electromagnetism: 1 Lecturer: Prof. Geraint F. Lewis.

From last time… Motion of charged particles

Gauss’ Law AP Physics C.

Cultural enlightenment time. Conductors in electrostatic equilibrium.

Chapter 23 Gauss’ Law Key contents Electric flux

Gauss’s Law Chapter 21 Summary Sheet 2.

Chapter 23 Gauss’s Law.

PHYS117B: Lecture 4 Last lecture: We used

By Squadron Leader Zahid Mir CS&IT Department , Superior University

Gauss’ Law AP Physics C.

Chapter 22 Gauss’s Law The Study guide is posted online under the homework section , Your exam is on March 6 Chapter 22 opener. Gauss’s law is an elegant.

By Squadron Leader Zahid Mir CS&IT Department , Superior University

Chapter 23 Gauss’s Law.

Presentation transcript:

Magnetic Force on Moving Charged Particles. Today’s agenda: Magnetic Fields. You must understand the similarities and differences between electric fields and field lines, and magnetic fields and field lines. Magnetic Force on Moving Charged Particles. You must be able to calculate the magnetic force on moving charged particles. Magnetic Flux and Gauss’ Law for Magnetism. You must be able to calculate magnetic flux and recognize the consequences of Gauss’ Law for Magnetism. Motion of a Charged Particle in a Uniform Magnetic Field. You must be able to calculate the trajectory and energy of a charged particle moving in a uniform magnetic field.

Magnetic Flux and Gauss’ Law for Magnetism We have used magnetic field lines to visualize magnetic fields and indicate their strength. B We are now going to count the number of magnetic field lines passing through a surface, and use this count to determine the magnetic field.

If the surface is tilted, fewer lines cut the surface. The magnetic flux passing through a surface is the number of magnetic field lines that pass through it. B A Because magnetic field lines are drawn arbitrarily, we quantify magnetic flux like this: M=BA. B  If the surface is tilted, fewer lines cut the surface. If these slides look familiar, refer back to lecture 4!

A = A cos  so M = BA = BA cos . We define A to be a vector having a magnitude equal to the area of the surface, in a direction normal to the surface. A  B  The “amount of surface” perpendicular to the magnetic field is A cos . Because A is perpendicular to the surface, the amount of A parallel to the magnetic field is A cos . A = A cos  so M = BA = BA cos . Remember the dot product from Physics 1135?

If the magnetic field is not uniform, or the surface is not flat… divide the surface into infinitesimal surface elements and add the flux through each… B dA your starting equation sheet has if possible, use

If the surface is closed (completely encloses a volume)… …we count lines going out as positive and lines going in as negative… B dA a surface integral, therefore a double integral But there are no magnetic monopoles in nature (jury is still out on 2009 experiments, but lack of recent developments suggests nothing to see). If there were more flux lines going out of than into the volume, there would be a magnetic monopole inside.

Gauss’ Law for Magnetism! dA Therefore B Gauss’ Law for Magnetism! dA This law may require modification if the existence of magnetic monopoles is confirmed. Gauss’ Law for magnetism is not very useful in this course. The concept of magnetic flux is extremely useful, and will be used later!

Congratulations! You are ½ of the way to being qualified to wear… You have now learned Gauss’s Law for both electricity and magnetism. These equations can also be written in differential form: Congratulations! You are ½ of the way to being qualified to wear…

The Missouri S&T Society of Physics Student T-Shirt! This will not be tested on the exam.