Hooke's Law (Edexcel International AS Physics)

Revision Note

Lindsay Gilmour

Last updated

Hooke's Law

  • When a force F is added to the bottom of a vertical metal wire of length L, the wire stretches
  • A material obeys Hooke’s Law if:

The extension of the material is directly proportional to the applied force (load) up to the limit of proportionality

  • This linear relationship is represented by the Hooke’s law equation:

ΔF = kΔx

  • Where:
    • F = applied force (N)
    • k = spring constant (N m–1)
    • Δx = extension (m)

 

  • The spring constant is a property of the material being stretched and measures the stiffness of a material
    • The larger the spring constant, the stiffer the material

  • Hooke's Law applies to both extensions and compressions:
    • The extension of an object is determined by how much it has increased in length
    • The compression of an object is determined by how much it has decreased in length

Load extension and force, downloadable AS & A Level Physics revision notes

Stretching a spring with a load produces a force that leads to an extension

Force–Extension Graphs

  • The way a material responds to a given force can be shown on a force-extension graph
  • A material may obey Hooke's Law up to a point
    • This is shown on its force-extension graph by a straight line through the origin

  • As more force is added, the graph may start to curve slightly

4-5-hookes-law-graph_edexcel-al-physics-rn

The Hooke's Law region of a force-extension graph is a straight line. The spring constant is the gradient of that region

  • The key features of the graph are:
    • The limit of proportionality: The point beyond which Hooke's law is no longer true when stretching a material i.e. the extension is no longer proportional to the applied force
      • The point is identified on the graph where the line starts to curve (flattens out)

    • Elastic limit: The maximum amount a material can be stretched and still return to its original length (above which the material will no longer be elastic). This point is always after the limit of proportionality
      • The gradient of this graph is equal to the spring constant k

Worked example

A spring was stretched with increasing load.

The graph of the results is shown below.

WE - hookes law question image, downloadable AS & A Level Physics revision notes

What is the spring constant?

Step 1: Rearrange Hooke's Law to make the spring constant the subject

k equals fraction numerator capital delta F over denominator capital delta x end fraction

Step 2: Compare the gradient to the equation in Step 1

    • This graph is length - extension, so the gradient gives:

fraction numerator i n c r e a s e space i n space y over denominator i n c r e a s e space i n space x end fraction equals fraction numerator capital delta x over denominator capital delta F end fraction

    • Therefore k is the reciprocal of the gradient

Step 3:  Find the gradient

4-5-hooke_s-law-we-solution-step-3_edexcel-al-physics-rn

Step 4: Calculate gradient

g r a d i e n t space equals space fraction numerator capital delta x over denominator capital delta F end fraction space equals space fraction numerator left parenthesis 0.145 space minus space 0.10 right parenthesis over denominator 0.36 end fraction space equals space 0.125

Step 5: Calculate the spring constant by finding the reciprocal of the gradient

k space equals space fraction numerator 1 over denominator 0.125 end fraction space equals space 8.0

Step 6: Write the answer, including units

    • Spring constant, k = 8.0 N m−1

Examiner Tip

Always double check the axes before finding the spring constant as the gradient of a force-extension graph. Exam questions often swap the force (or load) onto the x-axis and extension (or length) on the y-axis.

In this case, the gradient is not the spring constant, it is 1 ÷ gradient instead.

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Lindsay Gilmour

Author: Lindsay Gilmour

Expertise: Physics

Lindsay graduated with First Class Honours from the University of Greenwich and earned her Science Communication MSc at Imperial College London. Now with many years’ experience as a Head of Physics and Examiner for A Level and IGCSE Physics (and Biology!), her love of communicating, educating and Physics has brought her to Save My Exams where she hopes to help as many students as possible on their next steps.