Presentation is loading. Please wait.

Presentation is loading. Please wait.

I I. Magnetic field similar to a bar magnet For a very long solenoid, the magnetic field can be considered to be confined to the region inside the coils.

Published byDarwin Kimberly Modified over 10 years ago

Similar presentations

Presentation on theme: "I I. Magnetic field similar to a bar magnet For a very long solenoid, the magnetic field can be considered to be confined to the region inside the coils."— Presentation transcript:

1 I I

2

3 Magnetic field similar to a bar magnet For a very long solenoid, the magnetic field can be considered to be confined to the region inside the coils.

4 2a2a z x 2a2a

5 x z a z r  x components cancel z >> a  a r

6 i At a point along the axis z >> a current loop in xy-plane magnetic dipole moment right hand screw rule

7 H B Diamagnetic material  m < 0 (small) B =  o (1+  m ) H Permeability  =  o (1+  m ) =slope of B-H line

8 Ideal magnetic material or paramagnetic material  m > 0 (small) B =  o  r H =  H  = constant = slope of B-H curve B H

9 L11.5 : Magnetization If H is large or substance strongly magnetic (e.g. ferromagnetic), as H increases, the magnetization M (and hence B) may increase nonlinearly: Measure from the graph So  r varies with H. Could also use “differential permeability” High field region where slope decreases is called "saturation" region.

10 L11.6 : Magnetization Hysteresis Ferromagnetic materials also show a “hysteresis” effect, where decreasing the applied magnetic field, or H, doesn’t produce the reverse effect of increasing the field: B r = “remanence” or “residual magnetism” H c = “coercivity”

11 L11.7 Magnetization “hard” magnetic materials: H c is high, area of the loop is large, used for permanent magnets. “soft” magnetic materials: H c is small, area of loop is small, used for transformer cores & electromagnets. Material can be demagnetized by striking or heating it, or go round the hysteresis loop, gradually reducing its size. "Degaussing"

12 L9.1 : Magnetic fields due to currents Magnetic fields are produced by currents. Biot-Savart law Ampere’s law Example: so

13 L9.2 : Magnetic fields due to currents A solenoid: (n is number of turns/length) Therefore(inside)

14 L9.3 : Magnetic fields due to currents Use the Biot-Savart law to derive the magnetic field on the axis of a current loop: and Therefore

15 L9.4 : Magnetic fields due to currents Magnetic field of the Earth

16 L9.5 Magnetic fields due to currents The magnetic field of a magnetic dipole: This magnetic field has the same shape as the electric field of an electric dipole: do the exercise in the Exercise Set. (I  , A  0)

17

18 w t I B - + + + + + + + - - - - - - - - - charge carriers are electrons for copper Right hand rule  electrons are deflected down  bottom of probe is negative Z X Y

19 w t I B Z X Y

20 M  HM  H Saturation of M coercivity retentivity (remanence) Saturation of M Area enclosed = energy dissipated in a cycle in reversing the magnetic domains

21 A B C D F J E K H I L I G

Download ppt "I I. Magnetic field similar to a bar magnet For a very long solenoid, the magnetic field can be considered to be confined to the region inside the coils."

Similar presentations

Magnetic Fields Produced by Conductors

Magnetic Fields Produced by Conductors
Magnetic field.

Magnetic field.
Magnetic Fields Due To Currents

Magnetic Fields Due To Currents
Magnetic Field due to a Current-Carrying Wire Biot-Savart Law

Magnetic Field due to a Current-Carrying Wire Biot-Savart Law
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
We have looked at the magnetic field from a single loop of wire

We have looked at the magnetic field from a single loop of wire
Basic Electronics Ninth Edition Grob Schultz

Basic Electronics Ninth Edition Grob Schultz
MAGNETISM. The Earth Magnetic Poles North and South Geographic Poles North and South Earth is a giant magnet.

MAGNETISM. The Earth Magnetic Poles North and South Geographic Poles North and South Earth is a giant magnet.
Magnetic Properties. Introduction Magnetism arises from the Magnetic Moment or Magnetic dipole of Magnetic Materials. When the electrons revolves around.

Magnetic Properties. Introduction Magnetism arises from the Magnetic Moment or Magnetic dipole of Magnetic Materials. When the electrons revolves around.
Lesson 9 Dipoles and Magnets. Class 27 Today we will: learn the definitions of electric and magnetic dipoles. find the forces, torques, and energies on.

Lesson 9 Dipoles and Magnets. Class 27 Today we will: learn the definitions of electric and magnetic dipoles. find the forces, torques, and energies on.
Sources of Magnetic Field Chapter 28 Study the magnetic field generated by a moving charge Consider magnetic field of a current-carrying conductor Examine.

Sources of Magnetic Field Chapter 28 Study the magnetic field generated by a moving charge Consider magnetic field of a current-carrying conductor Examine.
UNIVERSITI MALAYSIA PERLIS

UNIVERSITI MALAYSIA PERLIS
Wednesday, Mar. 29, 2006PHYS 1444-501, Spring 2006 Dr. Jaehoon Yu 1 PHYS 1444 – Section 501 Lecture #17 Wednesday, Mar. 29, 2006 Dr. Jaehoon Yu Solenoid.

Wednesday, Mar. 29, 2006PHYS , Spring 2006 Dr. Jaehoon Yu 1 PHYS 1444 – Section 501 Lecture #17 Wednesday, Mar. 29, 2006 Dr. Jaehoon Yu Solenoid.
Electromagnetism Topics Covered in Chapter 14: 14-1: Ampere-turns of Magnetomotive Force (mmf) 14-2: Field Intensity (H) 14-3: B-H Magnetization Curve.

Electromagnetism Topics Covered in Chapter 14: 14-1: Ampere-turns of Magnetomotive Force (mmf) 14-2: Field Intensity (H) 14-3: B-H Magnetization Curve.
Magnetism 1. 2 Magnetic fields can be caused in three different ways 1. A moving electrical charge such as a wire with current flowing in it 2. By electrons.

Magnetism 1. 2 Magnetic fields can be caused in three different ways 1. A moving electrical charge such as a wire with current flowing in it 2. By electrons.
5. Magnetostatics Applied EM by Ulaby, Michielssen and Ravaioli.

5. Magnetostatics Applied EM by Ulaby, Michielssen and Ravaioli.
ELECTROMAGNETIC THEORY EKT 241/4: ELECTROMAGNETIC THEORY PREPARED BY: NORDIANA MOHAMAD SAAID CHAPTER 4 – MAGNETOSTATICS.

ELECTROMAGNETIC THEORY EKT 241/4: ELECTROMAGNETIC THEORY PREPARED BY: NORDIANA MOHAMAD SAAID CHAPTER 4 – MAGNETOSTATICS.
Ampere’s Law. General Statement Magnetic fields add as vectors, currents – as scalars.

Ampere’s Law. General Statement Magnetic fields add as vectors, currents – as scalars.
Magnetic Field Chapter 28 opener. A long coil of wire with many closely spaced loops is called a solenoid. When a long solenoid carries an electric current,

Magnetic Field Chapter 28 opener. A long coil of wire with many closely spaced loops is called a solenoid. When a long solenoid carries an electric current,
Magnetism Magnetism is the force of attraction or repulsion of a magnetic material due to the arrangement of its atoms, particularly its electrons. Like.

Magnetism Magnetism is the force of attraction or repulsion of a magnetic material due to the arrangement of its atoms, particularly its electrons. Like.

Similar presentations

Ads by Google