Physics - Electricity 2024 PDF

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This document contains notes about electricity, including static electricity, electrical energy, circuits, and different types of circuits. It also covers conductors and insulators.

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Physics - Electricity
Overview:
Static Electricity
Electrical Energy
Energy in Circuits
Making Electrical Circuits
Ohm’s Law
Series and Parallel Circuits
Ohmic vs Non-Ohmic Devices
Modern Electronics
1. Static Electricity
How do Atoms create a charge?
How can a static charge be made?
What moves to cause a potential difference?
Electricity occurs at the atomic level.
Review: The Atom
Matter is made up of atoms.

+ Proton (positively charged) sub-atomic particle
– that cannot easily move.
neutron (neutral): no charge.
+
+
Neither positive or negative
+

– electron (negatively charged) sub-atomic particle
– –
that can move from one substance to another.

atom nucleus
Where do charges come from?

Rubbing materials does NOT create electric charges. It just
transfers electrons from one material to the other.

Watch the Ted Ed Talk: The Science of Static Electricity
- https://www.youtube.com/watch?v=yc2-363MIQs

Discuss
Where do charges come from?
When a balloon rubs a piece of wool...
Electrons are pulled from the wool to the
– +
balloon.
– +
–
– + The balloon has more electrons than usual.
–
– +
wool + The balloon: – charged,
The wool: +charged
 workbook pg 3

Static Electricity
Static electricity: A build up of charge in an object that remains at rest

Proton: Positively (+ve) charged sub-atomic particle that cannot easily move.

Electron: Negatively (-ve) charged sub-atomic particle that can move from one
substance to another.

Neutral atom: No Charge.
Neither positive or negative.
Equal number of protons and electrons
 workbook pg 3

When something is positively charged:
Positive (+): Charge on a substance
due to fewer electrons than protons.

Negative (-): charge on a substance
due to more electrons than protons.

Atomic Structure
Experiment 1: Static Electricity See logbook

Aim: To Find Out a) How To Charge Objects and
b) About The Effects Of Charges.
Equipment
Plastic charging rods, Glass charging rod, woolen and other cloths, tiny bits of
paper or polystyrene, container of salt and pepper, paper plates.

What to do
1. Rub the plastic rod vigorously with a woollen cloth.
2. Bring it near tiny bits of paper or polystyrene. Does it attract or repel them?
3. Test a charged rod by bringing it:
a) near a single hair (or the hairs on your arm)
b) near a thin smooth stream of water from the tap.
c) near a container of salt and pepper.
4. Repeat steps 1 and 2 using different cloths.
5. Rub the glass rod vigorously with a cloth and check if you get the same
results.
2. Electrical Energy
1. Circuits
2. Energy and current are different
3. Materials provide resistance to electric currents
Circuits
WHAT ARE THEY ALL ABOUT?
 Video :
How a circuit Watch the Twig video on Circuits

works https://www.twig-world.com/
film/circuits-1555/

Discuss your findings
Conductors and Insulators
CONDUCTORS INSULATORS

Materials which allow electrons to flow Materials which electrons cannot pass through.
Examples: metals such as gold and iron. Examples: rubber, wood, plastic, glass
Challenge: Making the right connections
Use the PHET simulation https://phet.colorado.edu/sims/html/circuit-construction-kit-dc/latest/circuit-construction-kit-dc_all.html
Make the following circuit
Once the globe in the circuit lights up swap the settings from
pictures to circuit symbols
Challenge: Making the right connections
Copy these symbols into your workbook

2

That are not
connected
 See logbook

Experiment 3: Conductors vs insulators
Conductors – allow electricity to flow
Insulators – stop electricity from flowing

✓Set up circuit like I have in pHet
✓Test each material and complete the table
✓Answer the questions (in full sentences and with detail!)
3. Energy in Circuits
1. Voltage is a measure of potential difference
2. Current is the rate of movement of electrons
3. Resistance opposes voltage
Electric Circuit Basics
All electrical circuits consist of 3 things to make them work:

1. A power supply to provide the electrical energy.
2. A load (or loads) in which electrical energy is converted into other useful
forms of energy. e.g. a light globe. (Loads provide resistance to current flow
and energy is used up to overcome this resistance.)
3. A conducting path that allows electric charge to flow around the circuit.
 Power Supply
Batteries store chemical energy in the
substances inside them. This chemical
energy is transformed into electrical energy
when a chemical reaction takes place inside
the cell. The electrical energy you use from a
powerpoint comes from a power station,
which is different to a battery.
Current & Voltage
Electric current is the flow of electrical charge, just like you learnt with static
electricity. Current is the measure of the amount of electric charge passing a
particular point in an electric circuit every second.

The current is caused by the flow of electric charge (electrons in metals),
however, electric current is defined as the direction of the movement of
positive charge. Electric current is said to flow through a circuit from the
positive terminal to the negative terminal of the power supply.
Conventional Current vs Electron Flow
Electricity was first discovered in 1752 by Benjamin Franklin by flying a kite in a thunderstorm.
He decided that electricity was the flow of charge from positive to negative.
It wasn’t until 1897 that J. J. Thompson discovered the electron and as a consequence
scientists realised they had got electric charge wrong!
In metals it was the negatively charged electrons flowing causing a current not positively
charged particles.
In a solution of salts where both positive and negative charges are free to move then
conventional current is the directions the positive charges move and electron flow is in the
opposite direction.
Since it had been established for over 100 years that current represented the flow from
positive to negative the decision was made to not change the rules so if we talk about what
electrons do we use the term electron flow, which is always opposite to conventional current.
What is electricity?
Video:
Watch the Twig Video: ‘What is Electricity?’
https://www.twig-world.com/film/what-is-electricity-1540/

Write down 3 things you learnt.
Current, Voltage & Charges in Circuits
Current is a measure of how quickly the Voltage is a measure of how much energy each
charges move. Just as a water current in charge has.
a river.
The voltage is the amount of fuel the car has.
A petrol station is like a battery in a circuit as it
An analogy is consider a car as a charge. adds (energy) to the car.
The current is the speed the car is travelling.

NOTE: the car itself is not used up just like
charges in a circuit are not used up.
Voltage is the amount of energy possessed by a fixed quantity of electric
charge (called a Coulomb). As the charges move through the circuit they lose
voltage as it is converted to other energy forms such as heat, light, sound or
kinetic, this loss is called voltage drop (often also incorrectly called voltage).
Another name for voltage drop is potential difference as it measures a change
in potential (stored) energy of charge as it moves between one place and
another. As electric charge moves through a circuit it gains electrical energy
from the power supply and loses the same amount of energy as it passes
through the circuit.

i.e. the voltage gain across the terminals of the power supply is equal to the
total voltage drop across the rest of the circuit.
 Load
This is the energy converter in the circuit. This is where most of the electrical energy
carried by the charge is transformed into useful forms of energy such as light, heat and
sound. Every Load provides resistance to the flow of the charges.
4. Resistance
Is any opposition to the flow of charge through a circuit
is measured using the units ohm (Ω) and is represented by
the letter R.

Video: https://www.youtube.com/watch?v=8jB6hDUqN0Y
Conducting path
Pathway which allows the flow of electricity

Usually made of metals such as copper, which have little
resistance

Low resistance means that the electricity flows freely and
energy is not lost due to friction (heating of the pathway).
Resistance
how hard it is for the current to pass through
higher resistance means more energy needed
for current to flow through
a resistor is any component that restricts the
flow of electrons
unit: Ohms (Ω)
symbol: R
a multimeter (connected in parallel) can be
used to measure the resistance of a device
(load).
Example:

1st Band: Green = 5
2nd Band: Blue = 6
3rd Band: Multiplier = Orange = 1000

Value: 56 x 1000 = 56,000 Ohms
 1st Band: Brown = 1
1st Band: Brown = 1 2nd Band: Black = 0
2nd Band: Black = 0 3rd Band: Multiplier = Red = 100
Your turn: 3rd Band: Multiplier = Brown = 10
Value: 10 x 10 = 100 Ohms
Value: 10 x 100 = 1,000 Ohms

1st Band: Brown = 1
1st Band: Brown = 1
2nd Band: Black = 0
2nd Band: Black = 0
3rd Band: Multiplier = Blue = 1,000,000
3rd Band: Green = 5
Value: 10 x 1,000,000 = 10,000,000Ohms
4th Band: Multiplier = Brown = 10
Value: 105 x 10 = 1,050 Ohms
5. Making Electric Circuits
1. Electricity will only flow through a complete circuit
2. Electrical circuits can be planned and drawn using diagrams
3. Circuit components are shown using standard symbols
 Electric circuits
SERIES PARALLEL

Series and parallel circuits
https://www.youtube.com/watch?v=x2EuY
qj_0Uk
 Electric circuits
SERIES
In this type of circuit all components are
connected one after the other. This means
there is only one loop for the electric current to
flow through. An example is the torch we
looked at before. The circuit must be complete
in order for the electrons to flow and create an
electric current.
Series Circuit Characteristics
In a series circuit the electrical energy is shared amongst each globe.
As you add more globes the brightness of each will dim.

The current flowing in a series circuit does not change as there is only
one path for the electrons to flow. So the current at the beginning of the
circuit will be the same in the middle and at the end.

If one globe was to burn out then this would create a break in the circuit
and hence no other globes would work as the circuit is then not
complete.
Example
Consider the following circuit containing identical lamps A, B and C in
series.

(a). Describe the brightness of the three lamps.
Each will have the same brightness however they will be
dim.
(b) Compare the currents that flow through lamp A and
lamp C.
The brightness of A and C will be the same
(c). If the filament in bulb B burns out, will any of the
lights remain lit? Explain.
If B goes out the whole circuit will not work as this
provides a hole in the circuit.
PARALLEL

In a parallel circuit, there is more
than one resistor (bulb) and they are
arranged on many paths. This
means electricity (electrons) can
travel from one end of the battery
through different branches to the
other end of the battery.
From the above, it is clear that electricity from the battery can take either path A or
Path B to return to the battery. The great thing about parallel circuits is that, even
when one resistor (bulb) burns out, the other bulbs will work because the
electricity is not flowing through one path.

Think of all the light bulbs in your home. If one bulb burns out, the other bulbs in
the rooms still work.
Another great thing is that the bulbs in a parallel circuit do not dim out like the
case in series circuits. This is because the voltage across one branch is the same
as the voltage across all other branches.
Example:
Consider the following circuit containing identical lamps A, B and C parallel. These
lamps are the same as those for Circuit in the series example previously.

(a). Describe the brightness of the three lamps.
Each globe will glow brightly with the same intensity
(b) Compare the currents that flow through lamp A and lamp C.
The currents through A and C are the same.
(c). Compare the brightness of the lamps in this circuit to their
brightness in the series circuit. Explain any differences.
The brightness in the lamps for the parallel circuit is more intense
than the series circuit as the supply voltage is not shared amongst
the globes like in the series circuit.
A switch Scenario Question

L2 and L3

L2 and L1

no globes will work
Short Circuits:

When there is a path within a circuit which has
no resistance (or very little) the current will take
this path. This is known as a short circuit. Often
a short circuit can lead to a device becoming
hot or catching on fire. The other components
in the circuit will therefore not operate.
Example
Draw on the circuit below which path the current will take when the switch
is open and when the switch is closed?
 PHET simulator

Voltage, current and
Videos resistance
https://www.youtube.com
/watch?v=J4Vq-xHqUo8
Re-cap
Current = flow of charges (electrons) through a circuit

We use an ammeter, set up in series, to measure the current in amps or milliamps

Voltage = amount of energy that the charges (electrons) have at a given
point. A difference in voltages at different parts of a circuit is called a
voltage drop or a potential difference (change in stored energy between two
points in the circuit).

We use a voltmeter, set up in parallel, to measure the volts.
6. Series and Parallel Circuits
1. In series circuits, components are connected one after another
2. In parallel circuits, components are on different branches
 Series circuits
Comparing the voltage and current in series circuits. – PHET simulator

✓As more loads are added to the circuit, there is a decrease in current.
✓Light globes become more dim as you increase the number of loads within the circuit.
✓The current is the same throughout each load within the circuit.
✓Sum of the voltage drops across each load = voltage (potential) of the power supply.
 Parallel circuits
Comparing the voltage and current in parallel circuits – PHET simulator

✓Two loads/globes added in parallel = increase in current.
✓Both lights glow brightly.
✓The sum of the current flowing through each branch = overall current of the circuit.
✓Voltage is consistent across each load.
 1. Draw circuits for the following:
✓ One 6V battery, two light globes in series, one
switch between the battery and the first light
globe, a voltmeter measuring the potential
difference across the first light globe.
✓ One 6V battery, two light globes in parallel, one
switch that controls the whole circuit, one
ammeter measuring the current from the
battery, one voltmeter measuring the potential
difference across one light globe.
Tasks ✓ One 6V battery, two light globes in series, one
in parallel, one switch that controls the globes
in series only, an ammeter measuring the
current across the globe that’s in parallel.
✓ For the above: Comment on the brightness of
the lamps, the current and voltage flowing
through each lamp.
Terminology
Electricity: flow of charge
Electric current: flow of moving charges, from positive to negative terminals
Electron Flow: electrons flowing from negative to positive)
Voltage: amount of energy charges have at a given point
Current: rate of flow of charges (in wires; electrons)
Using Ammeters and Voltmeters Khan
Academy
AMMETERS VOLTMETER video
➔ A device that measures the size of the ➔ A device that measures the voltage (energy
electric current flowing in a circuit between two points in a circuit)
➔ Unit: amps (A) or milliamps (mA) ➔ The unit for voltage is: volts (V)
➔ Ammeters must be connected in series ➔ Voltmeters must be connected across a source or
➔ Positive (red) closer to positive of power load i.e. in parallel
supply. ➔ a voltmeter or multimeter in parallel measures
voltage
➔ Connect positive (red) terminal of voltmeter or
multimeter to red terminal of battery
Always start on the highest value. If your reading is too low, then move to the smaller one.
Remember to read the scale according to the positive terminal you’re connected to.
 workbook pg 24

Measurements in electric circuits
Ammeter
◦ A device that measures current.
◦ Unit: Amperes (A) or Amps, we also use milliamperes (mA), meaning
smaller current because currents are often very small.
◦ The symbol for an ammeter is:
Measurements in electric circuits
Ammeter:
◦ Ammeters must be connected in series, i.e. in the path of the circuit.
◦ Connect positive (red) terminal of the ammeter to the positive terminal of battery
◦ Use the positive terminal with the highest value first
◦ Use the scale which matches the connected positive terminal
◦ Always read the ammeter from directly in front, not side on.
Ammeter
The positive terminal of the ammeter is closest to
the positive terminal of the power supply
Connected in series
Measurements in electric circuits
Voltmeter
◦ Used to measure:
◦ the voltage gain across the terminals of a power supply.
◦ the voltage drop across parts of an electric circuit
◦ Measured in volts (V)
◦ The symbol for a voltmeter is:
 Measurements in electric circuits
Voltmeter:
◦ Voltmeters must be connected across a source or load i.e. in
parallel.
◦ a voltmeter or multimeter in parallel measures voltage
◦ connect positive (red) terminal of voltmeter or multimeter to
positive terminal of battery.
Errors in measurement
When reading scales errors can occur because often
an estimation is being made.

This voltmeter can be read as 2.3 V. Due to the
thickness of the needle it could be 2.29 V or 2.31 V.
 Errors in measurement
Random errors:
Caused due to estimation
When the quantity being measured changes randomly and quickly: temperature of water in a saucepan.

Systematic errors:
Due to incorrect use or limitations of equipment ie scale not on zero when not connected to the circuit
Results may be consistently low or high.
Errors in measurement
Reducing errors:
Random errors can be reduced by repeating measurements several times and finding an
average.
Some systematic errors can be eliminated by using the equipment correctly.
If an instrument doesn’t give a ‘zero’ reading when it should, the amount it is ‘off’ can be added
or subtracted from the result.
Investigation- Series & Parallel Circuits

✓Use PhET simulation
https://phet.colorado.edu/sims/html/
circuit-construction-kit-dc/latest/circui
t-construction-kit-dc_all.html
✓Read method
✓Construct circuits
✓Draw a diagram of each circuit
✓Record results and answer
questions as you go.
7. Ohm’s Law
1. Electrical current is proportional to voltage
2. Voltmeters measure potential difference
3. Ammeters measure current
Ohmic Conductors
 page 35 of booklet

Ohmic conductors
Current( A) Voltage (V)
2 4
4 8
6 12
8 16
10 20
Examples
1. For the circuit shown below, the voltage across the battery is 6V and
the current flowing through the globe is 2 A. Find the resistance of the
globe
R = V/I

R=6/2

R = 3 Ohms
Examples
Examples
3. If the voltage across a resistance is doubled, what will happen to the
current?

Answer: The current will double as well.

Explanation: If you look at the equation V= IR, if R stays the same then if
you multiply voltage by 2 (double the voltage), you must also double the
current for the equation to remain true.
Examples
4. A resistor of 3Ω is connected to a 9V battery. What is the current
flowing through the resistor?

I = V/R

I=9/3

I=3A
Examples
5. A current of 10A flows through a conductor of 4 Ω. What voltage
drop occurs over the conductor and therefore what is the size of the
battery?

V = IR

V = 10 x 4

V = 40 Volts
8. Ohmic vs Non-ohmic Devices
Ohmic devices obey Ohm’s Law V = RI and have linear V-I graphs
Ohmic devices have a constant resistance
Non-ohmic devices have a varying resistance and don’t obey Ohm’s Law
Non-ohmic conductors
Non-ohmic conductors do not follow Ohm’s law.

When graphing Voltage v Current, the graph is non-linear

E.g: LEDs, globes
 page 35 of booklet

Non-ohmic conductors
Current(A) Voltage (V)
1 1
2 4
3 9
4 16
5 25
9. Modern Electronics
1. Advances in digital circuits opened up many possibilities in electronics
2. Graphene to make small 2D circuits
3. Electronic sensors have many applications
Graphene