Download presentation
Presentation is loading. Please wait.
Published byClemence Armstrong Modified over 8 years ago
1
Magnets & Electromagnets Pg. 378 - 385
2
Auroras Have you ever seen the Northern lights? (aurora borealis) Did you know that you are really watching the interplay of electricity and magnetism? Why do they move and swirl?
3
Permanent Magnets 1. Where is the magnetic field the strongest? At the poles! **the magnetic field lines of a bar magnet are similar to the electric field lines of an electric dipole **while iron filings will align with the magnetic field, the electric dipoles align with the electric field
4
Permanent Magnets Recall that the magnetic field lines of a bar magnet extend from the north pole to the south pole outside the magnet and from south to north inside the magnet, forming a closed loop. (gr. 11) Magnetic field lines always form closed loops – you can never have only a south pole or only a north pole
5
Permanent Magnets Just as opposite electric charges attract, opposite magnetic poles attract The effect is different – when like poles approach each other, they repel……but….magnetic poles are electrically neutral
6
Permanent Magnets - summary All magnets have magnetic poles Opposite poles attract and like poles repel A magnetic field surrounds all magnets and flows from north to south outside the magnet and from south to north inside
7
Earth’s Magnetic Field The largest magnet on Earth is Earth itself If we were to place compasses at different spots in Earth’s magnetic field, each compass needle would be aligned parallel to the field **Earth’s north geographic pole is actually a south magnetic pole **It is convention to refer to this south magnetic pole as Earth’s north magnetic pole http://www.esa.int/spaceinvideos/Videos/2013/11/Magnetic_field_an_introduction
8
Earth’s Magnetic Field Earth’s magnetic field affects the motion of cosmic rays Charged particles entering Earth’s magnetic field are deflected and spiral along the field lines toward the magnetic poles This motion results in a concentration of charged particles at Earth’s north and south magnetic poles (i.e. the aurora borealis and aurora australis)
9
Earth’s Magnetic Field The circled x on the right indicates that the force is directed into the page for that particle and vice versa for the particle on the left (….right-hand rule) To find the direction of the force of a magnetic field: Point fingers in the direction of the velocity Curl fingers to the direction of the magnetic field Thumb points in the direction of the force
10
Earth’s Magnetic Field Our knowledge of what causes Earth’s magnetic field is incomplete, but several clues point to an explanation Earth’s magnetic poles move slowly from day to day and year to year Second, geological studies show that Earth’s magnetic field has completely reversed direction many times during the planet’s history
11
Earth’s Magnetic Field Electric currents in Earth’s core probably cause this behaviour of the magnetic field Earth’s core is made of liquid metal which conducts electricity The spin of Earth on its axis causes the liquid to circulate much like the current in a conducting loop……which causes a magnetic field Scientists believe that circulation within Earth’s core has a complicated flow pattern that varies with time….these variations cause changes in the magnetic field
12
Earth’s Magnetic Field (summary) Resembles that of a bar magnet Changes orientation over time Is able to redirect the motion of charged particles from space (auroras)
13
Did you know? Scientists have discovered many living creatures that use Earth’s magnetic field in different ways: Magnetotactic bacteria (photo) Honey bees Homing pigeons Dolphins *the dark round dots inside the cell are magnetite crystals
14
Electromagnetism In 1820, Danish physicist Hans Christian Oersted was demonstrating how a wire becomes warmer when electric charge flows through it In the course of his demonstrating, he noticed that the needle in a nearby compass moved each time he switched on the electricity This strange event let Oersted to conclude that a magnetic field surrounds moving electric charges …..this is now known as the principle of electromagnetism
15
Electromagnetism Moving charges, like those in an electric current, produce a magnetic field Current in a straight wire or other long, straight conductor creates a magnetic field whose lines look like circles centred on the wire You can determine the direction of the magnetic field lines around a straight wire using the right-hand rule for a straight conductor
16
Electromagnetism If you make a circular loop from a straight wire and run a current through it, the magnetic field will circle around each segment of the loop The field is strongest inside the coil because the field lines are closer together To determine the direction of the magnetic field in coiled water, you must use the right-hand rule for a solenoid
17
Electromagnetism (summary) Moving electric charges produce a magnetic field Straight conductor Thumb points in direction of current Curled fingers indicate direction of magnetic field lines Coiled conductor Fingers curl in direction of current Thumb indicates direction of magnetic field lines through the centre of the cell (i.e.. Thumb points to the north pole) Pg. 385, #5
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.