CP13.1Elasticity revisited: linear vs non-linear behaviour; force–extension graphs; calculating energy stored in a spring

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Notes

Elasticity, springs and energy stored

Hooke's law

For a spring (and many other elastic materials) below the limit of proportionality:

F = k × e

F = force in newtons (N).
k = spring constant in N/m (a measure of stiffness).
e = extension in metres (m) — the change in length, NOT the new length.

A 100 N/m spring stretches 1 cm for every 1 N of pull.

Linear vs non-linear behaviour

A force–extension graph for a spring is a straight line through the origin (linear) up to the limit of proportionality. Beyond that, the line curves — extension grows faster than expected. If stretched too far, the spring is permanently deformed (passes the elastic limit) and will not return to its original length.

Region	Behaviour
Linear	F ∝ e — spring obeys Hooke's law
Beyond limit of proportionality	Curve — extension grows faster than F
Beyond elastic limit	Permanent (plastic) deformation

Energy stored in a stretched spring

The work done in stretching a spring is stored as elastic potential energy:

E = ½ × k × e²

E in joules (J), k in N/m, e in m.

This formula works while the spring obeys Hooke's law. Geometrically, the energy = area under the force–extension graph (a triangle for the linear region).

✦Worked example

A spring has spring constant k = 200 N/m. It is stretched by 5.0 cm.

Convert: e = 0.05 m.
F = k × e = 200 × 0.05 = 10 N.
Energy stored = ½ × 200 × 0.05² = ½ × 200 × 0.0025 = 0.25 J.

Core Practical (Paper 2): force vs extension of a spring

Suspend a spring; measure unstretched length. Add 100 g (≈1 N) masses one at a time and measure the new length each time. Plot force (y) vs extension (x). Gradient = spring constant. The straight-line region shows Hooke's law; the curved region shows where it breaks down.

Edexcel exam tip

A common pitfall — using length instead of extension. Extension = current length minus natural length. Always check what the question gives you. Also: when calculating energy stored, square the extension, not just the force; ½ k e², not ½ k e.

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Practice questions

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Question 13 marks
Calculate spring constant
Edexcel Paper 2F (Foundation)

A spring extends by 8.0 cm when a force of 4.0 N is applied.

Calculate the spring constant in N/m. (3 marks)
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Question 23 marks
Energy stored in a spring
Edexcel Paper 2H (Higher)

A spring has a spring constant of 25 N/m. It is stretched by 12 cm.

Calculate the elastic potential energy stored in the spring. (3 marks)
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Question 33 marks
Limit of proportionality
Edexcel Paper 2H (Higher)

A student stretches a spring and plots force against extension. The graph is straight up to a force of 6.0 N, then curves upwards.

(a) State what the straight-line region of the graph shows. (1 mark)
(b) Define the limit of proportionality. (1 mark)
(c) Beyond the elastic limit, the spring no longer returns to its original length. State the technical name for this behaviour. (1 mark)
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Flashcards

CP13.1 — Elasticity revisited: linear vs non-linear behaviour; force–extension graphs; calculating energy stored in a spring

7-card SR deck for Edexcel GCSE Combined Science — Leaves (batch 3) topic CP13.1

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