Topic 11: Electromagnetic Induction (HL)

Question 1

Define: magnetic flux density

Unit?

Answer 1

The magnetic field strength.

The force acting on a current, divided by the current and the length of the current element.

B = (F/IL)

Units: Tesla (T) or kgA^-1s^-2

Question 2

Derive the magnetic field force equation in terms of charge and velocity

Answer 2

F = B I L sinθ

as I = q/t

F = (BqL/t) sinθ

as L = vt

F = (Bqvt/t) sinθ

F = Bqv sinθ

Question 3

Define: magnetic flux

Units?

Answer 3

The product of an area, A, and the component of the magnetic field strength perpendicular to that area

Units: Weber, Wb or kgm²A^-1s^-2

Question 4

What is the equation for magnetic flux?

Answer 4

Φ = BA cosθ

Question 5

How can you determine the radius of a coil using the magnetic flux equation?

Answer 5

Φ = BA cosθ

as A = πr²

Φ = Bπr² cosθ

rearrrange for r

Question 6

As a coil turns in a magnetic field, how does the magnetic flux change?

Answer 6

It follows a cosine wave

Question 7

What does e.m.f. mean?

Answer 7

Electromotive force. The work done per unit charge when energy is transferred from other forms into electric energy.

Question 8

When a conductor of length l, moves up through a magnetic field going into the page, at a constant velocity, v. What happens?

Answer 8

A current flows to the left, and subsequently an e.m.f. is induced.

Question 9

What factors determine the magnitude of the induced e.m.f for a conductor in a magnetic field?

(3)

Answer 9

1. The velocity of the conductor
2. The magnetic flux density
3. The length of the conductor

Question 10

Derive the equation for e.m.f induced in a conductor moving through a magnetic field

Answer 10

As work done = Fd

Work done = BILΔx

E.m.f. = work done/charge = (BILΔx)/q

as q = It

E.m.f. = BILΔx/It

= BLΔx/t

= BLv

Question 11

One side of a rectangular coil of n loops is in a magnetic field, what is the formula for the e.m.f. induced

Answer 11

e.m.f = n (BLv)

Question 12

How is Fleming’s left hand rule applied to:

a) a conductor with a current flowing through it going into a magnetic field
b) a conductor in a magnetic field moving at a constant velocity

Answer 12

a) Index point in magnetic field direction, middle finger points in current, the thumb is the force on the conductor.
b) Index points in magnetic field direction, middle finger point in the direction of the conductor’s velocity, the thumb is the direction of the current induced.

Question 13

What factors will determine the magnitude of induced e.m.f for a coil in a magnetic field?

(4)

Answer 13

1. Magnetic flux density
2. Rate at which flux density changes
3. Area of the coil
4. Number of turns in a coil

Question 14

For a single turn coil, what is the equation for the e.m.f. induced in terms of differences?

Answer 14

e.m.f = ΔΦ/Δt

or

e.m.f. = Δ(BA)/Δt

Question 15

What e.m.f. would a 1Wbs^-1 change of flux induce?

Answer 15

1V across the conductor

Question 16

What is magnetic flux linkage?

Equation?

Answer 16

A magnetic flux passing through the coil is said to link the coil.

Magnetic flux linkage is the product of the number of turns in a coil and the flux passing through the coil.

Flux linkage = nΦ

Question 17

What is faraday’s law?

What is its equation?

Answer 17

The magnitude induced e.m.f in a circuit is equal to the rate of change of magnetic flux linkage.

e. m.f = -n (ΔΦ/Δt)
e. m.f = -n ((ΔBAcosθ)/Δt)

Question 18

What does the graph for magnetic flux linkage look like for a coil turning? (starting at perpendicular to the magnetic field)

What does the graph for the e.m.f. induced look like?

Answer 18

nΦ would follow a cosine graph

e.m.f would follow a sine graph

Question 19

What is Lenz’s law?

Where is it seen mathematically?

Answer 19

The direction of an induced e.m.f will be such that it will oppose the change the produced it.

This is shown as the negative sign on the faraday’s law equation.

Question 20

A north end of a magnetic is moving at constant velocity into a coil, in what direction does the induced current flow?

When it is leaving?

Answer 20

Entering: rightwards

Leaving: leftwards

Question 21

When a coil is fixed and a magnet rotates in the iron core, what will be induced?

Answer 21

An alternating e.m.f. would be induced, and hence an AC current as there is continuously changing magnetic flux in the coil.

Question 22

Why will a coil placed between two magnets continue to spin?

Answer 22

There would be a force acting up on one end and a force acting down on the other.

Question 23

What is a back e.m.f.?

Answer 23

When a coil spins in a generation, its magnetic flux linkage will be continuously changing (as it is at a different angle each time), inducing an e.m.f.

From Lenz’s law, we know this e.m.f. would act in the opposite direction to the current that drives the motor.

This is called back e.m.f.

Question 24

What happens to an e.m.f. - time graph when the rate of rotation of an AC generator is doubled?

Answer 24

• Double amplitude
• Half the time period

Question 25

In an AC system, what is the equation for the power dissipated at any instant?

Answer 25

P = I²R

Question 26

For an AC system what does the power - time graph look like for:

a) power dissipated at the instant
b) mean power

for time period, T.

Answer 26

a) Two peaks within the time period, T.
b) A horizontal line at half the value of P_max

Question 27

What are the symbols for:

a) Maximum power
b) Maximum current
c) Maximum e.m.f.

Answer 27

a) P_max
b) I₀
c) V₀

Question 28

What is the equation for:

a) Maximum power dissipated
b) Mean power dissipated

Answer 28

a) P_max = I₀²R
b) P_mean = 1/2 I₀²R

Question 29

How are the graphs of AC current and power dissipated related?

Answer 29

Power is always positive and at double the frequency of current

Question 30

What does mean AC power show?

Answer 30

The equivalent power output of a DC system

Question 31

What does the root mean square current show?

Answer 31

The value of direct current that would dissipate the same power in the resistor as an AC current with max current (I₀)

Question 32

What are the 6 equations for mean power?

Answer 32

P_mean = 1/2 I₀V₀

P_mean​ = I_rmsV_rms

P_mean​ = I_rms2R

P_mean​ = 1/2 I₀²R

P_mean​ = V_rms²/R

P_mean​ = 1/2 (V₀²/R)

Question 33

Steps in explaining how a transformer works

(6)

Answer 33

1. An alternating current is supplied to the primary coil
2. The AC current in the primary coil produces a magnetic field that links around a core made of a soft magnetic material, usually soft iron.
3. As the current in the primary coil is alternating, the magnetic field in the core alternates at the same frequency. The field reverses twice for every current cycle.
4. The shape of the core also means that the magnetic flux links with the secondary coil.
5. Since the secondary coil has a charging flux inside it, an induced emf appears across its terminals. If connected to an external load, a current will flow.
6. This means that energy has transferred from the primary to the secondary circuit through the core.

Question 34

What is a step down transformer?

What is the relationship between the number of turns on each coil?

Answer 34

Step down transformers reduce the voltage supplied (current increases)

N_S < N_P

Question 35

What is a step up transformer?

What is the relationship between the number of turns on each coil?

Answer 35

Step up transformers increase the secondary voltage (decreasing current).

N_S > N_P

Question 36

What does magnetically soft mean?

Answer 36

Gains and loses magnetism very quickly.

Not a permanent magnet.

Question 37

Why is iron used as the magnetic core?

What problems can this cause?

Answer 37

Iron is a good electrical conductor.

However, this means that the changing flux can induce eddy currents.

Question 38

What can be done to make an iron core more efficient?

Answer 38

The core can be split into slabs and laminated.

Increasing the electrical resistance, but having minimal impact on the magnetic properties.

This reduces eddy currents and heat/energy loss.

Question 39

What properties should the wires used in a transformer have?

Answer 39

• Should be enamelled or insulated
• The wire material should have a low resistivity

Question 40

What does the national grid use for power transfer and why?

Answer 40

They use step-up transformers for high voltage transmission, to reduce energy loss through the heating effect.

Question 41

Define: capacitor

Answer 41

A device used for storing and releasing charge. It consists of two charged plates separated by an insulator called a dielectric.

Question 42

Explain how a capacitor is charged

(3)

Answer 42

1. When the capacitor is in a circuit and an e.m.f. is supplied, the electrons are displaced from one of the plates to another.
2. The e.m.f. drives the electrons through the circuit until the potential difference between the plates is equal to that of the e.m.f.
3. At that point the capacitor is fully charged.

Question 43

Define: capacitance

Units?

Answer 43

The charge stored on one of the plates, per unit p.d. across the plates

Units: Farad (F) or A²s⁴kg^-1m^-2

Question 44

What is the equation for capacitance?

Answer 44

C = Q/V

where C is the capacitance in Farads

Q is charge

V is potential difference

Question 45

How can you determine capacitance from a charge - pd graph?

Answer 45

as Q = C V

y = m x

the capacitance would be the gradient

Question 46

What are the three equations for energy stored by capacitors?

How are they derived?

Answer 46

E = 1/2 QV [derived from work done]

E = 1/2 CV² [derived by substituting Q=CV into the first one]

E = 1/2 (Q²/C) [derived by substituting V=Q/C into the second equation]

Where Q is charge, C is capacitance, V is p.d.

Question 47

What is the dielectric equation?

How can you make capacitance the subject?

Answer 47

Q/A = ε₀ V/d

where Q is charge, A is area, ε₀ is the permittivity of free space, V is pd, d is distance between the plates.

Q/V = ε₀ A/d

C = ε₀ A/d

where C is capacitance

Question 48

How can you increase a capacitor’s capacitance?

Answer 48

1. Increase the area of the plates (rolled up)
2. Decrease the distance between the plates
3. Add a dielectric of higher ε value

Question 49

What are suitable materials for dielectrics?

Why?

Answer 49

Insulators which become polarized when an electric field is set up across them.

This is because the molecules are more negative on one side and more positive on the other. When a field is applied, they rotate to counter the field.

Question 50

What is the equation for electric field strength with a dielectric and what effect does this has?

Answer 50

E_total = E_capacitor - E_dielectric

As E_total = V/d

d is fixed so V must decrease

and Q=CV, V decreasing would mean that C increases.

Question 51

What rule do capacitors in parallel follow?

Answer 51

C_total = C₁ + C₂ + C₃ …

[Same rule resistors in series]

NOTE: the capacitor and resistance rules are SWITCHED

Question 52

Prove the capacitors in parallel rule

Answer 52

For capacitors in series, the potential difference between all of them is the same as the potential difference between each individual one.

From the conservation of charge, we know that Q_total = Q₁ + Q₂ etc.

In using Q=CV

CV = C₁V + C₂V + C₃V etc.

C = C₁ + C₂ + C₃ etc.

Question 53

What rule do capacitors in series follow?

Answer 53

1/C_total = 1/C₁ + 1/C₂ + 1/C₃

[Same as the rule for resistors in parallel]

NOTE: the capacitor and resistance rules are SWITCHED

Question 54

Prove the capacitors in series rule

Answer 54

Kirchhoff’s second law tells us that the total pd over the capacitors is equal to the sum of the pd over each individual one.

V = V₁ + V₂

Conservation of charge tells us that the charge on each resistor is the same

Q/C = Q/C₁ + Q/C₂ + Q/C₃

1/C_total = 1/C₁ + 1/C₂ + 1/C₃ etc.

Question 55

What factors will affect how long it takes for a capacitor to discharge?

(3)

Answer 55

1. Capacitance of the capacitor
2. Resistance of the resistor in the circuit
3. (pd across the capacitor)

Question 56

Derive the equation for the change in charge with respect to capacitance and resistance

Answer 56

Vc = IR

as I = ΔQ/Δt

ΔQ/Δt = Vc/R

as Vc = Q/C

ΔQ/Δt = Q/RC

ΔQ = - Q/RC Δt

[the negative sign is added because the charge stored has decreased]

Question 57

Define: time constant

Units?

Answer 57

The time constant is the taken for the current, charge, and potential difference to reach 1/e of what they were at t=0. (Around 37% of the original value).

It is given the τ (tau)

Units: usually seconds (s) but can be any unit of time

Question 58

What relationship does charge over time follow when a capacitor is discharging?

Answer 58

A negatively exponential relationship

Question 59

Derive the *accurate* version of the capacitor discharge equation

Answer 59

ΔQ/Q = - 1/τ Δt

1/Q dQ = -1/τ dt

[integrate]

lnQ - lnQ₀ = -t/τ

[take exponentials and solve for Q]

Q = Q₀e^-t/τ

Question 60

What is the fomula for current and pd when a capacitor is discharging?

Answer 60

It follows the charge formula (Q = Q₀e^-t/τ)

I = I₀ e^-t/τ

V = V₀ e^-t/τ

Question 61

How can you present the capacitor discharge equation as a linear relationship?

How could you find the time constant?

Answer 61

lnQ = -1/τ t + lnQ₀

y = m x + c

The gradient would be -1/τ so the time constant = - 1/gradient