Electronics 

Electronic materials are crucial to our life today, and electrical ‘resistivity’ tells us how good or poor a material is at conducting electricity.

We use materials with low electrical resistivity to transmit electrical power from generators, across grid distribution networks, and to homes and workplaces for use. Designers of electrical devices rely on knowing the resistivity of wire used in order to calculate the resistance of components.

These devices range in size from enormous machines such as wind turbines or industrial lifting equipment; motors or engines in electric vehicles and all-new electric aircraft; consumer products such as washing machines, hair dryers and ovens; and the nanoscale components within the computer chips found in smart devices, laptops, and mobile phones.  

In fact, modern computing is based on controlling the resistivity of semiconductor materials in a type of transistor (known as ‘field effect transistors’ using ‘CMOS’ technology).

Measuring electrical resistivity helps us to understand the properties of materials, to monitor manufacturing processes, and to select the best material for an application.

Use this experiment to find out more!

Download the file below for the quick guide for the Resistivity of a Wire experiment (requires login) or follow these brief instructions:

1. Click on the right hand wire post to move to the Select Wire screen.
2. Open the micrometer by dragging the thumbwheel down.
3. Choose a material and drag the unlabelled wire into the micrometer.
4. Close the micrometer and measure the wire's width.
5. Click on the wire while it's in the micrometer to return to the main screen.
6. Click on the switch to turn it on.
7. Measure voltage and current for a variety of contact positions on the wire.
8. Calculate resistance for each contact position. 
9. Plot resistance vs contact position and calculate the gradient of a line of best fit.
10. Multiply the line's gradient by the wire's cross-sectional area to obtain the wire's electrical resistivity.

Download the file below for full instructions for the Resistivity of a Wire experiment (requires log in).

Download the file below for activities for the Resitivity of a Wire experiment (requires login).

• QUICK ACTIVITIES: 5 quick activities to try
• ACTIVITY 1: Different wire lengths

(Available as separate downloads or all activities)

Download the file below for the background science behind the Resitivity of a Wire experiment (requires log in).

Electricity powers the modern world. It is essential for electronic devices, home appliances, travel and school, work and leisure.

The widespread use of electricity is because we can make so many components that have different electrical behaviours, and then combine them to make all sorts of devices and machines. These behaviours can be seen most easily by creating a graph of the electrical current (I) through a component against the potential difference (V) placed across it. This graph is known as a component’s IV characteristic.

The simplest component is the electrical resistor. These have fixed electrical resistance, which means the electrical current is proportional to the potential difference and the IV characteristic is linear. Resistors are vital to almost all electrical devices, from a mobile phone to the world’s most powerful supercomputer, a flashlight to electric vehicles, an electric toothbrush to a medical scanner, your internet router to a communications satellite, or a vacuum cleaner to air-conditioning.

Diodes are made of two different semiconductor materials joined together and only allow electricity to flow in one direcion through them. They are hugely important in electronics and electrical engineering. They are most often used to convert alternating current (AC) electricity to direct current (DC), for example to convert mains electricity into 12 V DC used for charging mobile devices. They are also widely used to protect electronic circuits by preventing unwanted currents. 

Filament lamps might not be used for lighting as much as they once were but they show interesting electrical effects. They contain a long, thin metal 'filament' that heats up when high electrical current is flowing, which results in it starting to glow and give off light. The heating also changes the filament's electrical resistance, which results in a non-linear IV characteristic.

This virtual experiment will allow you to explore the electrical behaviour of resistors, diodes and filament lamps. You can take measurements of current and potential difference, plot a graph of their IV characteristics, and find their resistance values.

Use this experiment to find out more!

Download the file below for the quick guide for the IV Characteristics of Devices experiment (requires login).

Download the file below for full instructions for the IV Characteristics of Devices experiment (requires log in).

Download the files below for activities for the IV Characteristics of Devices experiment (requires login).

• ACTIVITY 1: IV characteristics of resistors
• ACTIVITY 2: IV characteristic of a filament lamp
• ACTIVITY 3: IV characteristic of a diode
• ACTIVITY 4: Power consumption of resistors (advanced)
• ACTIVITY 5: Power consumption of  a filament lamp (advanced)

(Available as separate downloads or all activities)

Download the file below for the background science behind the IV Characteristics of Devices experiment (requires log in).

Electricity powers so much of our life today. We use metal wires to transmit electrical power from power generators, such as power stations, ‘PV’ (photovoltaic) devices and wind turbines, to our homes and workplaces.

We use ‘resistance’ to measure how easily materials allow electrical current to flow. It is vital to the design of power distribution networks over long distances to understand how the length of a metal wire affects its resistance.

On smaller scales, it is important to know how the length of a conducting wire changes its resistance for applications that use motors, from washing machines through to electric cars and industrial machines. Electricity is also used in heaters, from industrial furnaces for large-scale materials processing through to ovens, underfloor heating and kettles, and in all sorts of electronic devices, such as computers, screens and sensors.

Designing any of these applications to be efficient and effective requires understanding how electricity flows through the materials in the various devices.

Use this experiment to find out more!

Download the file below for the quick guide for the Resistance (of a wire) experiment (requires login).

Download the file below for full instructions for the Resistance (of a wire) experiment (requires log in).

Download the files below for activities and associated worksheets for the Resistance (of a wire) experiment (requires login).

• ACTIVITY 1: Effect of wire length on its resistance
• ACTIVITY 2: Effect of wire width on its resistance
• ACTIVITY 3: The resistance of different materials

(Available as separate downloads or all activities/all worksheets)

Download the file below for the background science behind the Resitance (of a wire) experiment (requires log in).