Newton's Laws of Motion (AQA GCSE Physics: Combined Science)

Exam Questions

2 hours11 questions
1a1 mark

Newton's second law can be written as an equation.

Which equation linking force (F), mass (m) and acceleration (a) describes Newton's second law correctly ?

Tick (✓) one box.

   

F space equals space m over a square
F space equals space m a square
F space equals space m space plus space a square
F space equals space m space minus space a square
1b1 mark

Newton's third law can be summarised in a single sentence. 

Complete the sentence. 

Choose answers from the box. 

Each answer can be used once, more than once or not at all.

adjacent opposite equal

 

     

Whenever two bodies interact, the forces they exert on each other are .............................. and ..............................

1c2 marks

A probe is sent into space from Earth. When in space, the rocket engines are active. 

Describe the motion of the probe.

Assume there are no resistive forces. 

1d2 marks

The engines are cut out to conserve fuel.

Describe and explain the motion of the probe following this.

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2a2 marks

In a classroom, students are performing an experiment to show the relationship between force and acceleration. 

The equipment is shown below in Figure 1.

5-7-e-2a

Complete the sentences.

     

In this experiment, a metre ruler is used to ..............................

   

In this experiment, a stop watch is used to ..............................

2b1 mark

The digital stopwatch used is shown in Figure 2.

5-7-e-2b

State the resolution of the digital stopwatch.

2c2 marks

Referring to Figure 1, describe how the students will increase the force on the trolley while keeping mass in the system constant.

2d3 marks

The trolley takes 0.50 seconds to pass the first chalk line interval. Each interval is 0.20 m across.

Calculate the speed of the trolley over this first interval.

Give your answer to 2 significant figures.

   

   

Speed (2 significant figures) = .................... m/s

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3a2 marks

Higher Only

Write down the definition of inertia.

3b3 marks

Higher Only

Complete the sentences. 

Choose answers from the box. 

Each answer can be used once, more than once or not at all.

directly

larger

inversely

smaller

 

     

For a given force, inertial mass is .............................. proportional to acceleration.

   

Larger inertial masses will experience .............................. accelerations.

   

Smaller inertial masses will experience .............................. accelerations.

3c4 marks

Higher Only

Four items (A, B, C and D) of different masses are placed on ice, as shown in Figure 1. The same force is exerted on each item.

5-7-e-3c-blocks-on-ice

Place the letters of each box in order of acceleration, from smallest acceleration to largest.

   

Smallest acceleration

  

   
 

  

   
 

  

   
Largest acceleration

    

3d3 marks

Higher Only

Force F in Figure 1 has a magnitude of 4.5 N.

Calculate the acceleration of object D.

   

   

Acceleration of D = .................... m/s2

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1a2 marks

A student carries out an experiment to determine the relationship between the force applied to an object and the object’s acceleration.

She sets up her apparatus as shown in Figure 1.

Figure 1

7UOdW-iw_fig1-5-6-medium-aqa-gcse-physics

She places a number of masses on top of the trolley and then removes them, one at a time, placing them on the mass hanger in order to increase the force.

Explain why she keeps the unused masses on top of the trolley.

1b2 marks

Table 1 below contains some of her results.

Table 1

Force Acceleration (m/s2)

0.2

0.29

0.4

0.57

0.6

0.86

0.8

1.24

1.0

1.43

Figure 2 shows the graph of the results the student has drawn.

Figure 2

fig-2-5-7-medium-aqa-gcse-physics

The results contain an anomalous result.

Circle this anomalous result on the graph and explain why you have circled this point.

1c3 marks

Use the graph to calculate the mass of the trolley. Clearly show your method.

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2a2 marks

A student draws Newton’s third law pair of force on a book, as shown in Figure 1.

Figure 1

fig-1-5-7-medium-aqa-gcse-physics

Fg is the gravitational force and FN is the normal reaction force.

State whether the student has drawn a Newton’s third law pair of forces correctly. 

Explain your answer.

2b2 marks

A child balances on a pogo stick as shown in Figure 2. The child and the pogo stick are stationary.

Figure 2

fig-2-5-7-medium-aqa-gcse-phy

Draw a Newton’s Third law force pair on Figure 2

2c3 marks

Using Newton’s Third law, explain how the forces on a person’s foot enables them to walk on the ground.

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3a2 marks

Using Newton’s First law, explain why a comet moves in a straight line at constant speed whilst travelling in space.

3b3 marks

Figure 1 shows the forces on a car that is travelling to the right.

Figure 1

fig1-q3b-5-7-aqa-medium-physics

Calculate the resultant force on the car. State an appropriate unit for your answer.

3c3 marks

The car initially accelerates at 0.25 m/s2.

Calculate the mass of the car.

3d2 marks

The car eventually reaches a top speed which it cannot go any faster.

State the acceleration of the car at this point. Explain your answer.

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4a3 marks

Higher Only

All objects have inertia.

Which of Newton’s Laws of motion is also called ‘the law of inertia’. Explain your reasoning.

4b3 marks

Higher Only

A trolley accelerates at 3.8 m/s2 when a force of 5.0 N is applied to it.

Calculate the inertial mass of the trolley.

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5a1 mark

A group of students apply a constant force of 0.5 N to a trolley with a mass of 200 g. They then measure the trolley's acceleration. 

They want to investigate how changing the mass of the trolley affects the acceleration of the trolley. 

Name a control variable in this experiment.

5b3 marks

The students increase the mass added to the trolley by 200 g each time and record the acceleration using light gates. 

They draw a predicted curve on Figure 2 using Newton's second law and neglecting the mass of the trolley.

Their actual data were recorded with crosses on the graph in Figure 2.

5-7-m-5b-inverse-proportional-mass

Use data from Figure 2 to show that mass and the actual values of acceleration are inversely proportional.

5c1 mark

Suggest why the actual values of acceleration are lower than those predicted. 

5d2 marks

The difference between the curves could be due to an external force acting. 

Calculate the magnitude of this external force on the trolley.    

   

External force = .................................... N

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1a5 marks

A driver is driving back from a grocery shop at constant velocity. The driver is wearing a seatbelt, but the bag of groceries on the back seat is not secured.

A dog runs into the road in front of the car and the driver breaks heavily to avoid it. The groceries hits the front windscreen of the car.

Explain why the groceries hit the front windscreen of the car.

Refer to the appropriate law of motion in your answer. 

1b4 marks

A man in a nearby house is baking bread.

Distracted by the commotion of the car outside, he drops a 1.0 kg ball of dough from a height of 1.5 m.

Neglect the effects of air resistance.

Calculate the final speed of the dough just before it hits the ground.

Use the Physics Equation Sheet.

Give your answer to 2 significant figures.

   

   

Final speed = .................................... m/s
1c4 marks

From the moment the bottom part of the dough touches the ground, it takes 0.040 s for the centre of mass of the dough to come to rest.

Calculate the magnitude of the resultant force on the dough.

Give your answer to 2 significant figures.

   

   

Resultant force = .................................... N

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2a3 marks

Sam is a veterinarian at a zoo. They are performing routine health inspections on the turtles and the rhinos today.

The animals must be sedate for these inspections and are pulled out of their enclosures on wheeled trolleys, as shown in Figure 1.

Figure 1

5-7-h-2a-rhino-and-turtle

Using the concept of inertia, explain why Sam can move the turtle on their own but three zookeepers are needed to move the rhino.

2b6 marks

Sam exerts a force F on the trolley. Following Newton's third law, the trolley exerts an equal force in the opposite direction. 

Explain how Sam causes the trolley to move forwards despite this, referring to the forces on Sam and the forces on the cart. 

2c3 marks

After the inspection, when Sam isn't looking the turtle rides the trolley down a hill (see Figure 2). A frictional force acts uphill.

Figure 2

screenshot-2023-02-24-at-14-25-45

Explain why the turtle accelerates down the incline of the hill.

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3a2 marks

Higher Only

A student places a trolley on an incline, as in Figure 1. Three masses are attached to the trolley via a string which passes over a pulley.

Figure 1

5-7-h3-a-trolley-incline

Ignore the effects of friction. 

Describe the origins of forces A and B.

3b4 marks

Force B can be described as W subscript straight T space sin open parentheses 30 degree close parentheses, where W subscript straight T is the weight of the trolley.

m is the total mass of the three weights on the end of the string.

The system accelerates to the right with acceleration a.

Using Newton's second law, derive the following expression for the system:

 

m g space minus space W subscript straight T over 2 space equals space open parentheses m space plus space W subscript straight T over g close parentheses space cross times space a,

where g is the acceleration due to gravity.

3c5 marks

Each mass on the end of the string is 100 g and the weight of the trolley is 5.0 N.

Calculate the acceleration of the system.

Give your answer to 2 significant figures.

   

   

Acceleration (2 significant figures) = .................................... m/s2

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