6.3 Electromagnetism

Question 1

what is a magnetic field?

Answer 1

a magnetic field is the region around a permanent magnet or a moving charge in which another body with magnetic properties will feel a force

Question 2

what do magnetic field lines show?

Answer 2

• the shape of the field

- the direction of the field

Question 3

magnetic field lines always go from…

Answer 3

NORTH to SOUTH

Question 4

what is the symbol for current going into the page?

Answer 4

a circle with a cross, think arrowhead moving away from you

Question 5

what is the symbol for current coming out the page?

Answer 5

a circle with a dot, think arrowhead coming towards you

Question 6

what do you always get around a wire carrying an electric current?

Answer 6

a magnetic field

Question 7

what is a solenoid?

Answer 7

a coil of wire

Question 8

what rule can be used to work out the magnetic field around a current carrying wire? and what are the two differences in the rule for a simple wire and a solenoid?

Answer 8

you use the right hand rule where…
thumb = current
fingers = field direction
FOR A STRAIGHT CONDUCTOR^

thumb = field direction
fingers = current (curl your fingers)
FOR A SOLENOID^

Question 9

when you have a current perpendicular to a magnetic field what happens?

Answer 9

a force is induced
(this force comes from the interaction between the magnetic field of the wire and the magnetic field of the external magnets)

Question 10

what rule can you use to work out induced force from a current carrying wire being perpendicular to a magnetic field?

Answer 10

Fleming’s left hand rule, where…
thumb = force
index = field
middle = conventional current (positive to negative)

Question 11

what is the equation for the induced force on a current carrying wire in a magnetic field?

Answer 11

F = BILsinϴ
where F = induced force
B = magnetic flux density
I = current in the wire
L = length of current carrying wire in the field

Question 12

when is the induced force from a current carrying wire in a magnetic field at its maximum?

Answer 12

when the current carrying wire and magnetic field are perpendicular, i.e F = BILsinϴ when ϴ = 90

Question 13

outline an experiment to investigate flux density (calculate B)

Answer 13

• set up a digital balance with a coil of wire in a magnetic field at 90 degrees on top of the balance, connect the wire to a circuit to produce a current, have an ammeter connected in series
• the power supply should be connected to a variable resistor to be able to alter the current, zero the balance when there is no current so the mass reading is only due to the electromagnetic force not the weight force, then turn on the power supply
• note the mass and current, then change the current by altering the variable resistor and record the new mass and current, do this for a range of currents and repeat to get averages
• convert the mass into force using w = mg, plot a graph of F against I and the gradient will be equal to B x L (because of F = BIL)
• measure gradient and divide by length, L, of wire in the field to get B, magnetic flux density

Question 14

what is the equation for magnetic flux when the area cuts through the field at 90 degrees?

Answer 14

Φ = B x A
magnetic flux (Φ) = magnetic flux density (B) x area at right angles to the flux (A)

Question 15

what is magnetic flux density measured in?

Answer 15

tesla, T

Question 16

what is magnetic flux measured in?

Answer 16

weber, Wb

Question 17

what is the equation for magnetic flux when the area that has been cut is not at 90 degrees to each other?

Answer 17

Φ = BAcosϴ

Question 18

what is magnetic flux density defined as? (in words)

Answer 18

magnetic flux density is a measure of the strength of the magnetic field and is defined by the equation for the force on a current-carrying conductor in a magnetic field, F = BILsinϴ

Question 19

what is 1 tesla equal to?

Answer 19

1 tesla is when a wire perpendicular to the field with a current of 1 ampere experiences a force of 1 newton per metre of length

Question 20

is tesla a large or small unit?

Answer 20

a very LARGE unit, the Earth’s magnetic field is roughly equal to about 60 micro tesla

Question 21

what is the equation for the induced force on a single charged particle in a magnetic field?

Answer 21

F = BQV

Question 22

how do you derive F = BQV?

Answer 22

F = BIL
I = Q / t
V = L / t so L = Vt
F = B x Q x Vt / t 
F = BQV

Question 23

how do charged particles move in a magnetic field? and why?

Answer 23

they are deflected in a circular path (circular motion) because the force is acting at right angles to the direction of motion, no net force so particles have constant speed

Question 24

how can you come to an equation for the radius of curvature of a charged particle in a magnetic field?

Answer 24

circular motion, centripetal force F = mv^2 / r
force on a charged particle F = BQV
BQV = mv^2 / r
r = mv / BQ

Question 25

what are velocity selectors used for?

Answer 25

velocity selectors are often used in mass spectrometers to ensure that the accelerated particles entering the magnetic field have the same velocity

Question 26

how do velocity selectors work?

Answer 26

velocity selectors use a magnetic and electric field perpendicular to each other, a stream of particles is fired at right angles to both these fields (with a range of speeds) with a device called a collimator

Question 27

what is the ratio for the undeflected ions coming out of a velocity selector?

Answer 27

BQV = Eq
V = E / B
therefore you can vary the speeds by changing the strength of the magnetic or electric fields

Question 28

what happens to the undeflected ions coming out a velocity selector?

Answer 28

they are passed through just a single magnetic field and will follow a curved path, then the mass can be determined using r = mv / BQ

Question 29

what is the formula for magnetic flux linkage? (for N number of loops for a coil)

Answer 29

NΦ or BANcosϴ (because Φ = BAcosϴ)

where ϴ is the angle between the field and coil

Question 30

what is the definition for electromagnetic induction?

Answer 30

electromagnetic induction is the process of inducing an e.m.f in a conductor when there is a change in magnetic flux linkage across the conductor

Question 31

what are the two things you can do to induce an emf in a flat coil or solenoid?

Answer 31

• moving the coil towards or away from the poles of the magnet
• moving a magnet towards or away from the coil

in both cases, the emf is caused by the magnetic field (or magnetic flux) which is constantly changing that passes through the coil, a current is produced when the circuit is complete

Question 32

what is Fleming’s left hand rule used for and what is Fleming’s right hand rule used for?

Answer 32

left hand rule —> MOTOR EFFECT, force, field and current
right hand rule —> GENERATORS, motion, field and current
(in both cases the current is conventional)

Question 33

what is Fleming’s right hand rule? and what does it show?

Answer 33

to show what happens when we move a coil or wire through a magnetic field in order to generate electric current

thumb = motion of wire
index = magnetic field
middle = induced current

Question 34

what is Faraday’s Law of electromagnetic induction?

Answer 34

Faraday’s Law of electromagnetic induction states that the magnitude of the induced emf is directly proportional to the rate of change of magnetic flux linkage

Question 35

what is the equation linked to Faraday’s Law of electromagnetic induction?

Answer 35

ε = -△NΦ / △t or 
ε = -△NBA / △t

Question 36

what does the minus sign in ε = -△NΦ / △t account for?

Answer 36

Lenz’s law

Question 37

what is Lenz’s law?

Answer 37

Lenz’s law states that the direction of ay induced emf or induced current is always in a direction that opposes the flux change that causes it (this law came about because of conservation of energy)

Question 38

if you’ve got a complete circuit and an emf is induced what direction will the current be in?

Answer 38

the same direction as the emf

Question 39

outline an experiment to investigate magnetic flux density

2nd method

Answer 39

• place two bar magnets a small distance apart with opposite poles facing each other, they should be far enough apart not to snap together, but otherwise as close as possible to give a uniform field
• get a search coil (this is a small coil of wire with a known number of turns, N, and a known area, A), connect it to a data recorder and set the recorder to measure the induced emf with a very small time interval between readings
• place the search coil in the middle of the magnetic field so that the area (A) of the coil is parallel to the surface of the magnets, start the data recorder, keeping the coil in the same orientation immediately move the coil out of the field
• an emf will be induced due to the magnetic flux density through the coil changing from max to zero as you remove the coil from the field
• use your data to plot a graph of induced emf against time
• using Faraday’s and Lenz’s law, estimating the area under the graph gives you an estimate for the total flux linkage
• flux linkage = NΦ or BAN so to find B, divide the total area by the N X A
• repeat this experiment several times and find the mean of your values for B

Question 40

how is a constantly changing induced emf produced in the coil of a generator?

Answer 40

the rotation of the coil within a magnetic field produces a constantly changing flux linkage through the coil, this in turn produces a constantly changing induced emf in the coil

Question 41

what is AC current?

Answer 41

electrical current that reverses its direction with a constant frequency

Question 42

what is the main difference between a motor and a generator

Answer 42

motor = putting in electrical energy to get kinetic energy
generator = putting in kinetic energy to get electrical energy

Question 43

what is the main difference between a motor and a generator?

Answer 43

motor = putting in electrical energy to get kinetic energy
generator = putting in kinetic energy to get electrical energy

Question 44

what does the graph look like for induced emf-time?

Answer 44

a sine graph (when a coil rotates at a constant frequency), parallel to field = O emf
perpendicular to field = max emf
parallel to field = O emf
perpendicular field (but other way round) = - max emf
parallel to field = O emf

Question 45

what is a transformer?

Answer 45

a transformer is a device that uses electromagnetic induction to either increase or decrease the size of a alternating voltage with little loss of power

Question 46

what is a transformer made up of?

Answer 46

consists of two coils of wire wrapped around an iron core

Question 47

how does a transformer work?

Answer 47

an alternating current flowing in the primary coil (or input coil) produces a changing magnetic field in the iron core, the changing magnetic field is passed through the iron core to the secondary (or output) coil, where it induces an alternating voltage of the same frequency as the input voltage

Question 48

where are transformers used?

Answer 48

the National Grid

Question 49

what do step up transformers do to the voltage?

Answer 49

INCREASE the voltage

Question 50

what do step down transformers do to the voltage?

Answer 50

DECREASE the voltage

Question 51

what is the turns ratio on a step up transformer?

Answer 51

more turns on the secondary coil

Question 52

what is the turns ratio on a step down transformer?

Answer 52

more turns on the primary coil

Question 53

are transformers 100% efficient?

Answer 53

no, they are not 100% efficient - some power is always lost however by using a laminated core (made up in layers) reduced power losses by reducing the size of eddy currents which reduces power loss

Question 54

what is an ideal transformer?

Answer 54

a transformer with 100% efficiency

Question 55

what is the equation for an ideal transformer?

Answer 55

Ns / Np = Vs / Vp = Ip / Is
where N = number of turns
V = voltage
I = current
(comes from power in = power out, IV = IV)

Question 56

why do you want a small current in transformers?

Answer 56

we want a small current to reduce power loss due to the resistance of the cables

Question 57

outline an experiment to investigate the number of turns and voltage of a transformer

Answer 57

• set up a transformer with coils of wire around the iron core with a low voltage ac power supply connected to the first coil and a voltmeter on both primary and secondary coils
• begin with five tuns on the primary and 20 on secondary (use ratio 1:2)
• turn on the ac supply to the primary coil, use a low voltage (remember transformers increase voltage, keep it at a safe voltage), record the voltage across each coil
• keeping Vp the same so its a fair test, repeat the experiment with different ratio of turns,
• you should find for each ratio of tuns Ns / Np = Vs / Vp

Question 58

outline an experiment to investigate the number of turns, voltage and current of a transformer

Answer 58

• set up a transformer with coil of wire around the iron core with a voltmeter and ammeter connected to each coil on either side and a variable resistor in the primary coil circuit
• torn on the power supply and record the current through the voltage across each coil
• leaving the number of turns constant adjust the variable resistor to change the input current, record the current and voltage for each coil then repeat this process for a range of input currents
• you should find for each current Ns / Np = Vs / Vp = Ip / Is