Section 10 - Capacitors

Question 1

What is a capacitor?

Answer 1

• An electrical component made up of two conducting plates separated by a gap or a dielectric.
• Used to store opposing charges and therefore energy.

Question 2

What is a dielectric?

Answer 2

An insulating material placed between the two plates of a capacitor.

Question 3

What is the name of the most common type of capacitor?p

Answer 3

Parallel plate capacitor

Question 4

What happens when a capacitor is connected to a power source (d.c.)?

Answer 4

• Positive and negative charges build up on opposite plates
• Uniform electric field is created between the plates
Potential difference builds up between the plates?

Question 5

Why does potential difference build up between the plates on a capacitor?

Answer 5

Plates are separated by an electrical insulator, so no charge can move between them.

Question 6

What is capacitance?

Answer 6

The charge stored per unit potential difference by a capacitor. quote formula

Question 7

What is the symbol for capacitance?

Answer 7

C

Question 8

What is the unit for capacitance?

Answer 8

Farad (F)

Question 9

C = Q / V is found on the data sheet

what do the symbols stand for?

Answer 9

C = Q / V

Where:
• C = Capacitance (F)
• Q = Charge (C)
• V = Potential difference (V)

Question 10

How many farads is a μF?

Answer 10

10^-6

Question 11

How many farads is a nF?

Answer 11

10^-9

Question 12

How many farads is a pF?

Answer 12

10^-12

Question 13

What units are capacitance values usually in and why?

Answer 13

• From microfarads to picofarads

* Because a farad is a huge unit

Question 14

What is the voltage rating of a capacitor?

Answer 14

The maximum potential difference that can be safely put across it.

Question 15

How can a bucket represent a capacitor?

Answer 15

Question 16

What is the relationship of Q and V?

Answer 16

Q is directly proportional to V.

Question 17

How can use investigate the relationship with Q and V with a capacitor and variable resistor?

Answer 17

Question 18

When investigating the relationship with Q and V, what does the graph of current against time look like?
How can you find the charge?

Answer 18

Question 19

What does the graph of Q-V look like?

What is the gradient?

Answer 19

Straight line through origin.

Gradient is capacitance

Question 20

How long do capacitors provide power for?

Answer 20

short amount of time

Question 21

As capacitor discharges, what decreases?

Answer 21

Voltage through the circuit

Question 22

Why are capacitors dangerous?

Answer 22

They can store charge until needed and then discharge all of their charge in a fraction of a second.
The capacitors contain enough charge to kill you

Question 23

What are some examples of capacitors?

Answer 23

Camera flash.

Back-up power supplies - using ultracapacitors - reliable power for short periods of time.

Smoothing out variations in D.C. voltage supplies - capacitor absorbs the peaks and fills in the troughs.

Question 24

What is permittivity?

Answer 24

A measure of how difficult it is to generate an electric field in a certain material.

Question 25

What is relative permittivity?

Answer 25

The ratio of permittivity of a material to the permittivity of free space.

Question 26

If permittivity is high, does it require more or less charge to generate an electric charge?

Answer 26

More charge

Question 27

What is the symbol for relative permittivity?

Answer 27

εr (where r is subscript)

Question 28

What is the unit for permittivity?

Answer 28

F/m

Question 29

What is the equation that defines relative permittivity?

Answer 29

εr = ε₁ / ε₀

Where:
• εr = Relative permittivity
• ε₁ = Permittivity of material 1 (F/m)
• ε₀ = Permittivity of free space (F/m)

(NOTE: Not given in exam)

Question 30

What are the units for relative permittivity?

Answer 30

No units

ratio

Question 31

What is another name for relative permittivity?

Answer 31

Dielectric constant

Question 32

Describe how a dielectric works.

Answer 32

When no charge is applied:
• Dielectric is made up of lots of polar molecules
• These all point in random directions

When charge is applied:
• Electric field is generated
• Negative ends of molecules are attracted to positive plate and vice versa, causing them to rotate and align with the electric field
• The molecules each have their own electric field which opposes the applied field of the capacitor. The larger the permittivity, the larger the opposing field is.
• The reduces the overall electric field, which reduces the potential difference needed to charge the capacitor.
• This means the capacitance increases.

Question 33

Describe how a dielectric behaves when no charge is applied to the capacitor.

Answer 33

• Dielectric is made up of lots of polar molecules

* These all point in random directions

Question 34

Describe how a dielectric behaves when a charge is applied to the capacitor.

Answer 34

• Electric field is generated
• Negative ends of molecules are attracted to positive plate and vice versa, causing them to rotate and align with the electric field
• The molecules each have their own electric field which opposes the applied field of the capacitor. The larger the permittivity, the larger the opposing field is.
• The reduces the overall electric field, which reduces the potential difference needed to charge the capacitor.
• This means the capacitance increases

Question 35

How does a larger permittivity of the dielectric affect the capacitance and why?

Answer 35

• The larger the permittivity, the larger the capacitance.
• Because a larger permittivity means the opposing field produced by the dielectric molecules is larger, so the potential difference needed to charge the capacitor decreases, which increases the capacitance.

Question 36

Give the equation for the capacitance of a capacitor relative to its dimensions and permittivity of the dielectric.

Answer 36

C = Aε₀εr / d

Where:
• C = Capacitance (F)
• A = Area of the plates (m²)
• ε₀ = Permittivity of free space (F/m)
• εr = Relative permittivity of the dielectric 
• d = Separation of the plates (m)

Question 37

How can you investigate how capacitance changes (C = Aε₀εr / d)?

Answer 37

Question 38

What else do capacitors store except for charge?

Answer 38

Energy

Question 39

Why is energy required when capacitors charge?

Answer 39

When a plate of a capacitor becomes charged, the charges on the plate are being forces together “against their will” (like charges repel).

Question 40

Describe the Q-V graph for a capacitor.

Answer 40

Straight line of positive gradient through the origin.

Question 41

How can energy stored in a capacitor be found from the Q-V graph?

Answer 41

It is the area under the graph.

Question 42

How is capacitance related to energy stored by the capacitor?

Answer 42

The greater the capacitance, the more energy is stored by the capacitor for a given potential difference.

Question 43

If energy supplied in charging a capacitor is E = VQ and energy stored in the capacitor is E = 1/2 VQ, then were is the other half of the energy stored?

Answer 43

Energy stored by the capacitor is half the energy supplied to the capacitor.

The rest is lost to the resistance of the circuit and the internal resistance of the battery.

Question 44

Give the 3 equations for the energy stored by a capacitor.

Answer 44

E = 1/2 x Q x V
OR
E = 1/2 x C x V² 
OR
E = 1/2 x Q² / C

Question 45

Describe the circuit used to investigate capacitor charging and discharging.

Answer 45

• Capacitor is in series with resistor, ammeter and power supply
• Voltmeter around capacitor
• Ammeter and voltmeter connected to data logger

(See diagram pg 134 of revision guide)

Question 46

Describe how charging a capacitor can be investigated.

Answer 46

• Set up equipment as shown
• Close the switch to connect the uncharged capacitor to the power supply
• Let the capacitor charge while the data logged records the potential difference and current
• When the ammeter reading is 0, the capacitor is fully charged

Question 47

Describe what occurs when a capacitor starts charging (in terms of charge, current and and pd).

Answer 47

1) When switch is closed, current starts to flow.
2) Electrons flow onto the plate connected to the negative terminal, which causes negative charge to build up.
3) This charge repels electrons off the other plate, causing it to become positive. The electrons are attracted to the positive terminal.
4) Equal but opposite charge on each plate causes a potential difference to be created.
5) As charge builds up on the plates, it becomes harder to more electrons to be deposited due to electrostatic repulsion.
6) When the pd is equal to the power supply pd, the current falls to 0.

Question 48

What stops current flowing between the two plates on a capacitor?

Answer 48

The insulator between then.

Question 49

What causes the potential difference across a capacitor?

Answer 49

The opposite charges on each plate.

Question 50

What happens to current as a capacitor charges?

Answer 50

It slows down until it reaches zero due to the increased electrostatic repulsion making it harder for electrons to be deposited.

Question 51

When does the current fall to zero in charging a capacitor?

Answer 51

When the potential difference across the capacitor equals the potential difference across the power supply.

Question 52

Describe the I-t graph for a capacitor charging.

Answer 52

• Starts at positive y-intercept
• Current decreases at decreasing rate
• Eventually reaches 0

Question 53

Describe the V-t graph for a capacitor charging.

Answer 53

• Starts at origin
• P.d. increases at decreasing rate
• Eventually reaches peak p.d.

Question 54

Describe the Q-t graph for a capacitor charging.

Answer 54

• Starts at origin
• Charge increases at decreasing rate
• Eventually reaches peak charge

Question 55

How can charge be found from an I-t graph for a capacitor charging?

Answer 55

• It is the area under the curve

* Because Q = I x t

Question 56

Describe how discharging a capacitor can be investigated.

Answer 56

• Set up equipment as shown
• First, charge the capacitor fully
• Close the switch to complete the circuit
• Let the capacitor charge while the data logged records the potential difference and current
• When the ammeter reading is 0, the capacitor is fully discharged

Question 57

Describe the I-t graph for a capacitor discharging.

Answer 57

• Starts at positive y-intercept
• Current decreases at decreasing rate
• Eventually reaches 0

Question 58

Describe the Q-t graph for a capacitor discharging.

Answer 58

• Starts at positive y-intercept
• Current decreases at decreasing rate
• Eventually reaches 0

Question 59

Describe the V-t graph for a capacitor discharging.

Answer 59

• Starts at positive y-intercept
• Current decreases at decreasing rate
• Eventually reaches 0

Question 60

What is Q₀ in capacitors?

Answer 60

The charge across a capacitor when it’s fully charged.

Question 61

What is V₀ in capacitors?

Answer 61

The potential difference across a capacitor when it’s fully charged.

Question 62

What is I₀?

Answer 62

The current in a capacitor circuit when charging or discharging it is started.

Question 63

What are Q₀, V₀ and I₀?

Answer 63

The peak values for each of charge, potential difference and current in a capacitor.

Question 64

Does current flow in the same direction when charging and discharging a capacitor?

Answer 64

No, in opposite directions.

Question 65

Remember to practice drawing out the I-t, Q-t and V-t graphs for capacitor charging and discharging.

Answer 65

Pages 134 and 135 of revision guide or page 314 and 315 of the textbook.

Question 66

What does the time taken to charge or discharge a capacitor depend on?

Answer 66

• Capacitance (C)

* Resistance (R)

Question 67

Why does capacitance affect the time to charge or discharge a capacitor?

Answer 67

Capacitance affects the amount of charge that can be transferred at a one potential difference.

(Since C = Q/V)

Question 68

Why does the resistance of the circuit affect the time to charge or discharge a capacitor?

Answer 68

The resistance affects the current in the circuit.

Question 69

Describe how charge, potential difference and current change with time as a capacitor is charged.

Answer 69

CHARGE AND POTENTIAL DIFFERENCE:
• Increase with exponential decay
• So over time they increase more and more slowly
CURRENT:
• Decreases with exponential decay
• So over time they decrease more and more slowly

Question 70

Give the equation for the charge across a capacitor as it is charged.

Answer 70

Q = Q₀(1 - e^(-t/RC) )

Where:
• Q = Charge of capacitor (C)
• Q₀ = Charge of capacitor when fully charged (C)
• t = Time since charging began (s)
• R = Resistance (Ω)
• C = Capacitance (F)

Question 71

Give the equation for the potential difference across a capacitor as it is charged.

Answer 71

V = V₀(1 - e^(-t/RC) )

Where:
• V = P.d. across capacitor (V)
• V₀ = P.d. across capacitor when fully charged (V)
• t = Time since charging began (s)
• R = Resistance (Ω)
• C = Capacitance (F)

Question 72

Give the equation for the current in capacitor circuit as it is charged.

Answer 72

I = I₀e^(-t/RC)

Where:
• I = Current (A)
• I₀ = Current when charging is started (A)
• t = Time since charging began (s)
• R = Resistance (Ω)
• C = Capacitance (F)

Question 73

Describe how charge, potential difference and current change with time as a capacitor is discharged.

Answer 73

CHARGE AND POTENTIAL DIFFERENCE:
• Increase with decrease decay
• So over time they decrease more and more slowly
CURRENT:
• Increases with exponential decay
• So over time they increase more and more slowly

Question 74

Give the equation for the charge across a capacitor as it is discharged.

Answer 74

Q = Q₀e^(-t/RC)

Where:
• Q = Charge of capacitor (C)
• Q₀ = Charge of capacitor when fully charged (C)
• t = Time since charging began (s)
• R = Resistance (Ω)
• C = Capacitance (F)

Question 75

Give the equation for the potential difference across a capacitor as it is charged.

Answer 75

V = V₀e^(-t/RC)

Where:
• V = P.d. across capacitor (V)
• V₀ = P.d. across capacitor when fully charged (V)
• t = Time since charging began (s)
• R = Resistance (Ω)
• C = Capacitance (F)

Question 76

Give the equation for the current in capacitor circuit as it is discharged.

Answer 76

I = I₀e^(-t/RC)

Where:
• I = Current (A)
• I₀ = Current when discharging is started (A)
• t = Time since charging began (s)
• R = Resistance (Ω)
• C = Capacitance (F)

Question 77

What is the symbol for the time constant?

Answer 77

τ

Question 78

What is the time constant, τ, when discharging?

Answer 78

• The time taken for the charge, potential difference or current of a capacitor to fall to 37% of its value when fully charged.
• It is equal to RC.

Question 79

What is the time constant, τ, when charging?

Answer 79

• The time taken for the charge or potential difference of a capacitor to rise to 63% of its value when fully charged.
• It is equal to RC.

Question 80

Derive the definition of the time constant, τ.

Answer 80

• When t = τ = RC,
• Q = Q₀e^(-t/RC) = Q₀e^-1
• So Q/Q₀ = e^-1 = 0.37
• Therefore, τ is the time for the charge of a fully charged capacitor to fall to 37% of its initial value.

Question 81

In practice, how many time constants does it take for a capacitor to fully discharge?

Answer 81

About 5RC or 5τ.

Question 82

How can you find the time constant, τ?

Answer 82

Either do τ = RC.
or
Read it from a Q-t or ln(Q)-t graph:
Discharging: 0.37Q₀
Charging: 0.63Q₀

Question 83

Remember to revise how τ is shown on a graph.

Answer 83

Pg 136 of revision guide

Question 84

How can the time constant be found from a Q-t graph for a discharging capacitor?

Answer 84

• Look at the point at which the charge is 37% of the initial charge
• Find the time taken for the charge to fall to that charge

Question 85

What graph can be plotted to find the time constant more accurately when discharging?

Answer 85

ln(Q) against t

NOTE: This also works with potential difference or current instead of charge

Question 86

Derive which graph should be plotted to find the time constant more accurately when discharging.

Answer 86

• Q = Q₀e^(-t/RC)
• ln(Q) = (-1/RC)t + ln(Q₀)
• This is now in the form y = mx + c.
• Plot ln(Q) against t. The gradient is -1/RC.

(NOTE: This also works for potential difference and current instead of charge.)

Question 87

What is the symbol for time to halve?

Answer 87

T(1/2)

Where 1/2 is in subscript.

Question 88

What is time to halve, T(1/2)?

Answer 88

• The time taken for the charge, current or potential different of a discharging capacitor to reach half of the value when fully charged
• 0.69RC

Question 89

What are the values to remember for the time constant (τ) and time to halve (T(1/2))?

Answer 89

Time constant:
• 0.37 of full charge when discharging
• 0.63 of full charge when charging

Time to halve:
• 0.69RC

Question 90

What is the equation for time to halve, T(1/2)?

Answer 90

T(1/2) = 0.69RC

Where:
• T(1/2) = Time to halve (s)
• R = Resistance in the circuit (Ω)
• C = Capacitance (F)

Question 91

Derive the equation for time to halve.

Answer 91

• We’re looking for the time when Q = 1/2 x Q₀
• So 1/2 x Q₀ = Q₀ x e^(-t/RC)
• 1/2 = e^(-t/RC)
• ln(1/2) = -t/RC
• ln(1) - ln(2) = -t/RC
• ln(2) = t/RC
• t = ln(2)RC
• t = 0.69RC

Question 92

Remember to practice deriving the equations for the time constant and time to halve.

Answer 92

Pgs 136 and 137 of revision guide.

Question 93

How can you tell if something is exponential decay?

Answer 93

It always takes the same length of time for the quantity to halve.