Elastic Potential Energy (Oxford AQA IGCSE Combined Science Double Award)

Revision Note

Elastic Potential Energy

Extension Tier only

What is elastic potential energy?

  • Energy in the elastic potential store of an object is defined as:

The energy stored in an elastic object when work is done on the object

  • This means that any object can change shape by stretching, bending or compressing (eg. springs, rubber bands)

    • When a spring is stretched (or compressed), work is done on the spring which results in energy being transferred to the elastic potential store of the spring

    • When the spring is released, energy is transferred away from its elastic potential store

The extension of a spring when a force is applied

Stretching a spring, for IGCSE & GCSE Physics revision notes
When a force is applied to either end of a spring, it stretches. Work is done on the spring as it extends, therefore energy is transferred

How to calculate elastic potential energy

  • The amount of energy in the elastic potential store of a stretched spring can be calculated using the equation:

Ee = ½ × k × e2

  • Where:

    • Ee = elastic potential energy in joules (J)

    • k = spring constant in newtons per metre (N/m)

    • e = extension in metres (m)

  • The above elastic potential energy equation assumes that the spring has not been stretched beyond its limit of proportionality

A spring stretched beyond its elastic limit

Elastic limit of a spring, for IGCSE & GCSE Physics revision notes
When a spring is stretched beyond its elastic limit it will no longer return to its original length

Worked Example

A mass is attached to the bottom of a hanging spring with a spring constant of 250 N/m. It stretches from 10.0 cm to 11.4 cm.

Calculate the energy in the elastic potential store of the stretched spring.

Step 1: Determine the extension of the spring

  • The extension of the spring is its extended length minus its original length

e space equals space 11.4 space minus space 10.0

e space equals space 1.4 space cm space

  • Convert cm to m

e space equals space fraction numerator 1.4 over denominator 100 end fraction

e space equals space 0.014 space straight m

Step 2: List the known quantities

  • Spring constant, k space space equals space 250 space straight N divided by straight m

  • Extension, e space equals space 0.014 space straight m

Step 3: Write out the elastic potential energy equation

E subscript e space equals space 1 half space cross times space k space cross times space e squared

Step 4: Calculate the elastic potential energy

E subscript e space equals space 1 half space cross times space 250 space cross times space open parentheses 0.014 close parentheses squared

E subscript e space equals space 0.0245 space straight J

Step 5: Round the answer to 2 significant figures

E subscript e space equals space 0.025 space straight J

Examiner Tip

Look out for units! If the question gives you units of cm for the length you MUST convert this into metres for the calculation to be correct.

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