GCSEScienceAQACombined Science: TrilogyPhysicsExam QuestionsForcesForces & Elasticity

Forces & Elasticity (AQA GCSE Combined Science: Trilogy: Physics): Exam Questions

Exam code: 8464

1 hour10 questions
Easy
Medium
Hard
1a
3 marks

Which of the following statements is correct about inelastic deformation?

Tick (✓) three boxes.   

 Object returns to its original length

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Object returns to its original shape 

square

Object does not return to its original length

square

Object does not return to its original shape 

square

Requires only one force 

square

Requires more than one force

square

How did you do?

1b
1 mark

What are the correct units for the force applied to a spring which makes it elastically deform?

Tick (✓) one box.   

square

N m 

square

N/m 

square

N

square

How did you do?

1c
1 mark

Which of the following options is the correct equation linking Force (F), spring constant (k) and extension (e)?

Tick (✓) one box.   

F space equals space k e squared

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F space equals 1 half k e

square

F space equals space k e

square

F space equals space 2 k e

square

How did you do?

2a
1 mark

Figure 1 shows a force-extension graph for a spring.

Figure 1

5-3-e-2a-force-extension-graph

Which marker on the force-extension graph shows the limit of proportionality?

    Choose your answer

    2b
    1 mark

    Which marker on Figure 1 shows the spring obeying Hooke's law?

      Choose your answer

      2c
      1 mark

      State the quantity given by the gradient of a force-extension graph.

      How did you do?

      3
      1 mark

      Write the equation linking elastic potential energy open parentheses E subscript e close parentheses, spring constant open parentheses k close parentheses and extension open parentheses e close parentheses.

      How did you do?

      1
      3 marks

      A newton meter, as shown in Figure 1, consists of a point connected to a metal spring.

      When a force is applied to the spring, the spring stretches, and the point moves along the scale to the maximum reading.

      Figure 1

      newton-meter

      Use the information provided in the diagram to calculate the spring constant of the spring.

      How did you do?

      2
      6 marks

      A student wishes to carry out an investigation to measure the spring constant of a metal spring.

      Describe a method that the student could use.

      Your answer should include detail of how accurate measurements may be taken and may also include a labelled diagram

      How did you do?

      3a
      6 marks

      The table below gives the results obtained by the student.

      Force in N

      Extension in cm

      2.0

      1.3

      4.0

      2.1

      6.0

      2.9

      8.0

      3.7

      10.0

      4.5

      12.0

      5.9

      The student finds that after stretching, the spring does not return to its original length.

      Plot a graph of force (y-axis) against extension (x-axis) on the grid below.

      q3a-5-3-aqa-gcse-physics

      How did you do?

      3b
      2 marks

      Mark the position of the elastic limit on the graph, using an X.

      Give your reason for choosing this point.

      How did you do?

      3c
      2 marks

      The student has made an error whilst calculating some of the results.

      Suggest what the error was and how the results could be corrected.

      How did you do?

      3d
      3 marks

      Use the graph to calculate the spring constant of the metal spring.

      How did you do?

      3e
      2 marks

      The student decided to repeat the experiment using a double spring set up, as shown in Figure 2

      Figure 2

      double-spring

      Add a line to your original graph showing the results you would expect the student to get.

      You should assume that the initial extension of the springs is the same as with the original experiment.

      How did you do?

      3f
      2 marks

      Explain how the elastic limit of the double spring will compare with the original spring.

      How did you do?

      4a
      2 marks

      Figure 3 shows three different stages in a bungee jump.

      Figure 3

      bungee

      Stage 1: The jumper is stationary and the bungee cord is slack

      Stage 2: The bungee cord has no slack, but is not yet exerting a force on the jumper.

      Stage 3: The jumper is at the lowest point and has temporarily stopped moving.

      Describe the change in energy stores that occur between stage 1 and stage 3.

      How did you do?

      4b
      3 marks

      Calculate the change in the jumper’s gravitational energy store between stage 1 and stage 2.

      The jumper has a mass of 60 kg (assume that the mass of the bungee cord is negligible).

      Gravitational field strength = 10 N/kg

      How did you do?

      4c
      1 mark

      State the energy in the jumper’s kinetic store at stage 2.

      How did you do?

      4d
      3 marks

      Calculate the speed of the bungee jumper at stage 2.

      How did you do?

      4e
      1 mark

      After reaching stage 2, the bungee cord starts to stretch, exerting an upwards force on the jumper which eventually brings the jumper to a stop at stage 3.

      Between stage 1 and stage 3 the jumper’s gravitational energy store decreases by a total of 18 000 joules.

      State the energy in the bungee’s elastic store at stage 3.

      How did you do?

      4f
      1 mark

      Calculate the extension of the bungee cord at stage 3.

      How did you do?

      4g
      3 marks

      Using an appropriate equation from the Physics equation sheet, calculate the spring constant of the bungee cord.

      You may assume that the bungee cord behaves like a perfect spring.

      How did you do?

      4h
      3 marks

      Use your answers to (f) and (g) to calculate the force exerted by the bungee cord on the jumper at stage 3.

      How did you do?

      4i
      2 marks

      At stage 3 the jumper's spine stretches a small but safe amount.

      Explain why

      How did you do?

      1a
      2 marks

      A group of physics students are investigating force and extension of a spring.

      One student obtained the results shown in Table 1.

      Table 1

      Mass / kg

      Force / N

      Mean total length / m

      Extension / m

      0

      0

      0.051

      0

      0.2

      1.96

      0.074

      0.023

      0.4

      3.92

      0.091

      0.017

      0.6

      5.88

      0.108

      0.017

      0.8

      7.84

      0.127

      0.019

      As the teacher came around to check the student's data, the teacher asked the student to think about why the extension data is not increasing.

      Identify the mistake the student has made in their data analysis process.

      How did you do?

      1b
      2 marks

      Another student plotted their graph, but the shape of the curve was different to everybody else's. 

      Figure 1 shows the student's graph.

      Figure 1

      5-3-h-1b-ef-graph

      Suggest what the student did to produce the graph shown in Figure 1.

      How did you do?

      1c
      1 mark

      Another student extrapolated their graph as shown in Figure 2.

      Figure 2

      5-3-h-1c-force-extension-extrapolation

      What is the significance of the point marked X?

      Tick (✓) one box.   

      X shows the original length of the spring 

      square

      X shows the average extension of the spring

      square

      X shows the final length of the spring after deformation

      square

      X shows the increased length of the spring after deformation

      square

      How did you do?

      2a
      1 mark

      Figure 1 shows a force-extension graph for a spring with a spring constant k.

      Figure 1

      5-3-h-2a-force-extension-k

      Draw a line on Figure 1 for a spring with a higher value of k.

      How did you do?

      2b
      5 marks

      A force of 6.0 N stretches a spring by 3.0 cm.

      Calculate the extension of the spring when a force of 4.5 N is applied.

      Give your answer in cm to 2 significant figures.

         Extension = .................................... cm

      How did you do?

      3a
      2 marks

      A student plotted a force-extension graph for a spring of spring constant k

      Figure 1 shows the graph they plotted.

      Figure 1

      5-3-h-3a-force-extension-anomaly

      The student has labelled one of the data points as anomalous. 

      State whether you agree with this choice, and explain your answer.

      How did you do?

      3b
      4 marks

      For the spring used in part (a), calculate the work done on the spring when a 3 N force is applied.

      Give your answer in the appropriate units.

         Work done = ......................... Units = ...........................

      How did you do?