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AQA GCSE Work done(Physics)

Work done

Work done means energy transferred. So, when work is done, energy is transferred from one energy store to another energy store. 

Example

The man lifts the box from the ground to above his head, so chemical potential energy store is transferred mechanically to gravitational potential energy store

The boy does 200J of work on the box, to raise its height. This means that the box will increase its gravitational potential energy store by 200J

Man lfing boxes showing the boxes increasing their gravitational potential energy store

Work done depends on:

Force

Distance moved in the direction of the force

 

The larger the force used, or the greater the distance the object travels, the greater the work done, or energy transferred.

Force is directly proportional to work done

Distance travelled in the direction of the force is also directly proportional to the work done

Examples of questions

1.A footballer kicks a ball with a forward force of 40N, the ball travels forward covering a distance of 30m. Calculate the work done
 
Work done = force x distance moved in the direction of the force
Work done = 40N x 30m = 1200J
 

2. The man has a weight of 500N and is being lifted upwards from the bottom platform to the upper platform by the escalator. Calculate the work done in lifting the man from the lower platform, to the upper platform.

 

In this case, the man is being lifted, so the force is acting upwards. Therefore the distance that should be used would be the 10m. 

Work done = force x distance moved in the direction of the force

Work done = 500N x 10m = 5000J

Practice Questions

1.A man lifts a box of fruit with a weight of 200N from the ground to 1.5m above the ground. Calculate the work done

2. A ferromagnetic crane lifts some scrap iron of weight 20kN upwards from the ground, travelling a distance of 350cm. Calculate the work done.

3. 40000J of work is done to push a car of weight 7000N along a length of road. Calculate how far the car travels. 

4. Sketch a graph to show the relationship between work done and force. Put work done on the Y axis and Force on the X axis. 

Need more questions, try our worksheets.

Answers to the questions above
physics worksheet

Energy stores and systems notes and questions

Real life energy transfers

Kinetic energy

Gravitational potential energy

Elastic Potential energy

Changes in energy, Specific heat capacity

Power

Conservation of Energy

Work done

Conduction

Wasted energy transfers

Efficiency

Energy Resources

Wind and Solar

Coal, Oil and Natural Gas

Nuclear Power

Biofuels

Hydroelectric, Wave and Tidal

Circuit Symbols

Electric Current and Charge

Potential difference, Current and Resistance

Resistors

Thermistors and Light Dependent Resistors

Series Circuit

Parallel Circuits

Series Circuit Calculations

Parallel Circuit Calculations

Alternating and Direct Electrical Circuits

Mains Electricity

Earth wire

Fuses

Electrical Power

Energy Transfer in Circuits

Power of Appliances

National Grid

Static Charge

Static Electricity

Static Electricity and Forces

Static Electricity and Sparking

Electric Fields

Electric Fields and Objects

Density

Measuring Density

States of Matter

Changes of state

Internal Energy

Specific Heat Capacity

Latent Heat

Specific Latent Heat

Heating and Cooling Curves

Specific heat capacity compared to Specific latent heat

Motion of gas particles 

Gas Pressure and Volume

Doing work on gases

Structure of the Atom

Absorption and Emission of EM Radiation

Mass Number and Atomic Number

Isotopes

Ionisation

JJ Thomson and Plum pudding model

Ernest Rutherford and the Nuclear Model

Niels Bohr changing the Nuclear Model

Discovering the Proton and Neutron

Radioactive Decay

Measuring radiation from radioactivity

Radiation types and properties

Random nature of radioactive decay

Half life

Half life calculations

Radioactive contamination or irradiation

Hazards of contamination and irradiation

Studies on the effects of radiation on humans

Background Radiation

Different half lives of radioactive isotopes

Uses of nuclear radiation

Nuclear Fission

Nuclear Fission Chain Reaction

Writing nuclear fission equations

Drawing and interpreting nuclear fission diagrams

Nuclear Fusion

Scalar and Vector Quantities

Contact and Non Contact Forces

Describing interactions of forces and objects

Gravity

Measuring Weight

Calculating Weight

Resultant Forces

Free body diagrams

Free body diagrams part 2

Resolving Forces

Forces and Equilibrium

Finding the resultant force, using the parallelogram rule

Finding the resultant force, using the parallelogram rule part 2

Work done and Forces

Forces and Elasticity

Hooke’s Law

Calculating Spring Constant

Using Force-extension graphs

Linear and Non linear force extension graphs

Work done and elastic potential energy

 

Introduction to moments

Levers

Balancing Moments

Balancing Moments made more complex

Gears

Gears and Moments

Pressure acting on a surface

Pressure at the surface of a fluid

Pressure due to a column of liquid

Explaining pressure in a column of liquid

Upthrust

Atmospheric Pressure

Distance and Displacement

Speed

Calculating Speed

Velocity

Distance-time graphs

Acceleration

Velocity time graphs and acceleration

Velocity time graphs and acceleration curved lines

Velocity time graphs and calculating acceleration

Velocity time graphs and distance travelled

Equation of Motion

Falling Objects

Terminal Velocity

Newton’s 1st Law

Newton’s 2nd Law

Newton’s 3rd law

Stopping distances

Reaction time

Braking distance

Momentum

Conservation of Momentum

Types of Collisions

Changes to Momentum

Designing Safety Features

Transverse Waves

Longitudinal Waves

Comparing Transverse and Longitudinal waves

Evidence for Waves

Characteristics of Waves

Measuring the speed of sound in air

Measuring the speed of ripples on the surface of the water

Changes to Sound Waves

Reflection of Waves

Reflection, Transmission and Absorption of Waves

Sound Waves

Sound Waves and the Ear

Using Waves to explore structures

Using Ultrasound Waves for medicine

Using Ultrasound for industrial imaging

Seismic Waves

Using Echo sounding

Introduction to Electromagnetic Waves

Electromagnetic Waves Transferring Energy

Electromagnetic waves interacting with matter

Building ray diagrams for refraction

Using wave front diagrams to explain refraction

Radio waves and oscillations

Changes to atoms and electromagnetic waves

Harmful Electromagnetic Waves

Uses for Electromagnetic waves

Lenses

Power of Lenses

Real and Virtual images

Drawing ray diagrams for a concave lens

Drawing Ray Diagram to produce a virtual image for a convex lens

Drawing ray diagram to produce a real image for a convex lens.

Magnification and lenses

Visible Light

Specular and Diffuse Reflection

Colours of White Light

Coloured Filters

Seeing Coloured Objects

Seeing Coloured Objects Part 2

Viewing objects through coloured filters

Transparent, Translucent and Opaque

Understanding Black body radiation

Perfect Black Body

Temperature of Bodies

Temperature of the Earth

Accordion Content

Accordion Content