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Physics 30S.  A changing magnetic field creates an electric field  A changing electric field creates a magnetic field  Basis for electricity generation,

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Presentation on theme: "Physics 30S.  A changing magnetic field creates an electric field  A changing electric field creates a magnetic field  Basis for electricity generation,"— Presentation transcript:

1 Physics 30S

2

3  A changing magnetic field creates an electric field  A changing electric field creates a magnetic field  Basis for electricity generation, transmission, most uses and applications

4  Complicated, but in essence:  Electric fields and magnetic fields are one phenomena: an electromagnetic field  United concepts of electricity and magnetism into 4 equations James Clerk Maxwell June 13,1831 – November 5, 1879

5  Faraday was a great researcher  Intuitive knowledge about electricity and magnetism  Performed many experiments which paved the way for an understanding of electromagnetism  Primitive motor September 22, 1791 – August 25, 1867

6  Oersted made one of the first electricity/magnetism insights all because of a messy desk  Current carrying wire caused compass needles to divert  Oersted’s basic principle of electromagnetism: moving electric charges produce a magnetic field August 14,1777 – March 9, 1851

7  Current through a wire creates a circular magnetic field; weakens with distance  Right Hand Rule 1:  Point thumb in the direction of the current  Make a fist  Fingers show direction of magnetic field  Magnitude of field: B is the magnetic field (T) I is the current (A) r is the distance from the wire (m)

8  Point your thumb in the direction of current flow  Fingers wrap to show direction of the magnetic field

9  Point your thumb with the current  Curl your fingers to determine the direction of the field

10  Permeability of free space  4π x 10 -7 Tm/A  Physical constant  Permeability relates the ability of the medium to induce a magnetic field  Inductance

11  Current  Coming out of the screen  Going into the screen  Meant to visualize an arrow

12 Add arrows to show the direction of the magnetic field

13

14 a) What is the strength of the magnetic field 15 cm away from a wire carrying 75 A? B = 1.0 x 10 -4 T b) At what distance is the strength of the magnetic field 1.5 x 10 -5 T? r = 1.0 m

15 a) How much current is a wire carrying if the magnetic field is measured to be 3.03 x 10 -3 T at 0.500 meters away? I = 7580 A b) What is the strength of the magnetic field 1.50 m from the wire? B = 1.01 x10 -3 T

16  3. Magnetic Fields Homework Handout

17  Current carrying wires experience a force in an external magnetic field  Right Hand Rule 2:  Make an L shape with your hand  Thumb points in the direction of the current  Fingers point in the direction of the magnetic field  Palm shows the direction of the force  Magnitude of the Force: B is the magnetic field (T) I is the current (A) l is the length of the wire (m) Θ is the angle between the magnetic field and the wire (not in the text)

18 What direction is the force on the wire? Solution: Into the screen

19 A 25cm wire in a motor carrying 15 A of current is in a magnetic field of 0.2T. What will be the force on the wire, assuming that the wire and magnetic field are perpendicular? F B = 0.08 N

20 What length of conductor, running at right angles to a 0.033 T magnetic field and carrying a current of 20.0 A, will experience a force of 0.10N? I = 0.15 m

21  Magnetic fields exert a force on moving electrical charges, including charged particles  What might the formula be?

22  An electron is shot through a cathode ray tube TV at 5.0 x 10 5 m/s, perpendicular to the direction of the field. If the force acting on the particle is 2.0 x 10 -15 N and the length of the tube is 10 cm, what is the strength of the magnetic field?  B = 0.025 T

23  An alpha particle (He 2+ ) is shot through a magnetic field at 3.33 x 10 6 m/s, perpendicular to the direction of the field. If the magnetic field strength is 1.5 x 10 -4 T, what is the magnitude of the force acting on the particle?  F = 1.6 x10 -16 N

24  Pg.569  Force on a Wire: #7-9  Pg. 574  Force on a Moving Particle: #10-11

25  Magnetic field hasn’t been defined qualitatively  Magnetic field is a force per unit current element  Electromagnetism is needed

26  A solenoid is our first electromagnet  Magnet caused by electricity

27  A solenoid is a coiled wire  Contains many loops  Magnetic field of each loop sums to make the magnetic field of the solenoid  http://webphysics.davidson.edu/Applets/BField/solen oid.html http://webphysics.davidson.edu/Applets/BField/solen oid.html  Capable of producing strong magnetic fields  Right Hand Rule 3:  Coil fingers with the direction of current  Thumb points in the direction of magnetic north  Magnetic field created is similar to a bar magnet

28  Right Hand Rule 3:  Coil fingers with the direction of current  Thumb points in the direction of magnetic north

29 Where are the North and South Poles?

30  Calculating Magnetic Forces Exercises Handout

31  Lab Manual 24.1

32

33  Pick from one among the list.  Research about how it works  Specifically, where is electromagnetism involved and how does it make the device function?  2 minute presentation at the end of class explaining the device to the class  Include multi-media if possible!  Questions?

34  Speakers  Cathode Ray Tubes/Television  Alarms  Electromagnets for Lifting Steel  Generators  Electric motors  Maglev trains

35  Primitive motor  Make the Motor  Generator  Reverse motor  Electromagnet  How do you think this works?  Speakers  http://electronics.howstuffworks.com/speaker5.htm http://electronics.howstuffworks.com/speaker5.htm  Cathode Ray Tube  Alarm/bell  Maglev trains  http://player.discoveryeducation.com/index.cfm?guidAssetId=6 581C80B-C521-4467-9A8A- E56533E3FC83&blnFromSearch=1&productcode=US http://player.discoveryeducation.com/index.cfm?guidAssetId=6 581C80B-C521-4467-9A8A- E56533E3FC83&blnFromSearch=1&productcode=US

36  Right Hand Rule 1:  Point thumb in the direction of the current  Make a fist  Fingers show direction of magnetic field  Right Hand Rule 2:  Make an L shape with your hand  Thumb points in the direction of the current  Fingers point in the direction of the magnetic field  Palm shows the direction of the force  Right Hand Rule 3 (Solenoids):  Coil fingers with the direction of current  Thumb points in the direction of the magnetic field

37  Day 1 -2: What is Electromagnetism, Maxwell, Oersted, Field around a wire,  Up to slide 16  Day 2: Force around a wire, Force on moving particles  Up to slide 24  Day 3: Definition of Magnetism, Solenoids, In-class work  Up to slide 26  Solenoid example  Day 4: Lab Experiment  Day 5: Electromagnet applications research, summary of right hand rules (Friday) – Gr. 11 up to here  Up to Slide 36  Day 6: Review  Day 7 Test


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