all about magnets!

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    Created by
    ella

    Cards (43)

    • how does electromagnetic induction work
      creating electricity by placing a wire in a moving field which produces current
    • electromagnetic induction
      the process of producing electricity from magnetism
    • motor effect
      electricity + magnetism -> movement
    • generator effect = electromagnetic induction
      movement + magnetism -> electricity
    • lenz’s law
      when the current induced opposes the motion
    • magnetic field
      a region where a magnetic material experiences a force
    • 3 magnetic materials
      iron , nickel , cobalt
    • what do magnetic fields show
      The size and direction of magnetic fields
    • what direction do magnetic field lines point
      north to south
    • what is another name for the strength of the magnetic field
      magnetic flux density
    • what is the magnetic field strength measured in?
      teslas (T)
    • how do u create a uniform field
      by placing the north and south of two permanent bar magnets near eachother - it creates a uniform field between the two poles
    • iron fillings to see magnetic fields
      put the magnet on a piece of paper and scatter the iron fillings on top . The fillings will align themselves with the field lines
    • how to use a compass to plot magnetic field lines
      • put the magnet on a piece of paper and place the compass on the paper , next to the magnet . the compass needle will point in the direction of the field lines in this position
      • mark the direction that the compass needle is pointing by making two dots on the paper , one at each end of the needle
      • move the compass so that the tail end of the needle is where the tip of the needle was previously . Repeat this then join up the the marks you have made
      • repeat this method at different points around the magnetic to for several field lines
    • like poles repel each other and unlike poles attract
    • when a magnet is brought near a magnetic material then that material acts as a magnet . This magnetism has been induced by the original magnet , the closer the two get , the stronger the induced magnet
    • permanent vs induced magnets
      induced magnets ( usually ) lose their magnetism once the magnet has been moved away
    • an electric current in a material produces a magnetic field around it . The larger the electric current , the stronger the magnetic field
    • a magnetic field around a straight , current-carrying wire is made up of concentric circles with the wire in the centre . You can find the direction of the field with the right-hand rule .
    • compasses can be used to show that there is a magnetic field and to find the direction of one
    • the further away from the wire , the weaker the magnetic field ( shown by the field lines getting further apart )
    • if the wire is bent into a loop , the magnetic field will still exist but now it'll look like a toroidal shape . If the wire is coiled tightly enough , the field inside the coil becomes very strong.
    • in electromagnetism , the strength of the magnetic field depends on the number of loops of wire , the size of the current flowing through them and how close the core is to the coil .
    • electromagnets are made when an iron core is placed within a solenoid ( a long, closely wound coil ). When a current flows through the coil , the magnetic fields produced by all the turns add together to make a much stronger magnetic field than if they were separate .
    • when an electric current flows through a solenoid , a magnetic field is produced along its length . This means that if the solenoid is placed over a compass needle , the compass needle will be deflected towards the solenoid .
    • in electromagnetic induction , a changing magnetic field causes a potential difference across a conductor which then creates an electric current .
    • electromagnets are used in motors , generators , transformers and MRI scanners .
    • to make an electromagnet , wrap some insulated copper wire round a piece of iron or steel about 10 times . Connect the ends of the wire to a battery and switch . When the switch is closed , the current flows through the wire and creates a magnetic field around the wire .
    • the magnetic field in the centre of a flat circular coil of wire is similar to a bar magnet . There are concentric ellipses ( stretched circles ) of magnetic field lines around the coil
    • the magnetic field inside a current-carrying coil is strong and uniform
    • the magnetic effect at the ends of the solenoid will increase if:
      • the current in the wire is increased
      • the number of turns ( e.g. the number of coils ) of the wire is increased but the length stays the same
      • the length of the solenoid is decreased but the number of turns stays the same
      • an iron core is added inside the solenoid
    • how to create a force on a wire
      when a current-carrying conductor ( e.g. a wire ) is put between magnetic poles , the two magnetic field affect one another . Result is a force on the wire
    • to experience the full force , the wire has to be at 90 degrees ( right angle ) to the magnetic field . If the wire runs along the magnetic field , it won’t experience any force at all , angles in between will feel force
    • how the force gets stronger
      if either the current or the magnetic field is made stronger
    • Changing the direction of either the current or the magnetic field will change the direction of the force
    • a good way of showing the direction of a force
      apply a current to a set of rails inside a horseshoe magnet . A bar is placed on the rails which completes the circuit . This generates a force that rolls the bar along the rails .
    • why do we use flemmings left hand rule?
      to find the direction of the force of a current-carrying conductor
    • how to use flemmings left hand rule
      • point your First finger in the direction of the magnetic Field
      • seCond finger in the direction of the Current
      • thuMb will point in the direction of the force ( Motion )
    • equation to calculate the force on a current-carrying conductor (e.g. a wire)

      force on carrying = magnetic x current x length
      conductor (N) flux density (A) (M)
      (T)
    • describe how to plot the magnetic field lines of a bar magnet with a compass
      • put the magnet on a piece of paper and put a compass next to it , marketing on the piece of paper the point at which the compass needle is pointing
      • then move the compass so that the tail end of the compass needle is where the tip of the needle was previously and mark against where the needle is pointing
      • repeat this several times and then join up the markings for a complete sketch of a field line around the magnet
      • do this several times for different points around the magnet to get several field lines