Combined Physics - 6.5

Question 1

What are physical quantities with only magnitude (and no direction)?

Answer 1

Scalar quantities

Question 2

What are physical quantities with magnitude and direction?

Answer 2

Vector quantities

Question 3

Give some examples of scalar quantities

Answer 3

• Speed
• Distance
• Mass
• Temperature
• Time

Question 4

Give some examples of vector quantities

Answer 4

• Force
• Velocity
• Displacement
• Acceleration
• Momentum

Question 5

What does the arrow for a vector quantity show?

Answer 5

The length of the arrow shows the magnitude and the direction of the arrow shows the direction of the vector quantity

Question 6

What is a force?

Answer 6

A push or pull acting on an object due to the interaction with another object

Question 7

What are forces between objects classified as?

Answer 7

Contact or non-contact forces

Question 8

Describe contact forces

Answer 8

Forces between objects that are physically touching

Question 9

Describe non-contact forces

Answer 9

Forces between objects that are physically separated

Question 10

Give some examples of contact forces

Answer 10

• Friction
• Air resistance
• Tension
• Normal contact force

Question 11

Give some examples of non-contact forces

Answer 11

• Gravitational force
• Electrostatic force
• Magnetic force

Question 12

What type of quantity is force?

Answer 12

A vector quantity

Question 13

What is weight?

Answer 13

The force acting on an object due to gravity

Question 14

What cause the force of gravity close to the Earth?

Answer 14

The gravitational field around the Earth

Question 15

If mass it constant, what can affect the weight of an object?

Answer 15

The gravitational field strength at the point where the object is

Question 16

How can the weight of an object be calculated?

Answer 16

Question 17

What are the units for gravitational field strength?

Answer 17

Gravitational field strength, g, measured in N/kg

Question 18

What is an object’s centre of mass?

Answer 18

The weight of an object acting at a single point

Question 19

What does W ∝ m mean?

Answer 19

The weight and mass of an object are directly proportional

Question 20

How is weight measured?

Answer 20

A calibrated spring-balance (newton meter)

Question 21

What is a ‘resultant force’?

Answer 21

A single force, replacing a number of forces, acting upon an object

Question 22

What has happened if a resultant force moves an object?

Answer 22

Work is done

Question 23

What is the equation for work done?

Answer 23

Question 24

When a force causes an object to move through a distance what has happened?

Answer 24

Work is done on the object so a force does work on an object when the force causes a displacement of the object

Question 25

What is one joule of work done?

Answer 25

When a force of one newton causes a displacement of one metre

Question 26

What does 1 joule equal?

Answer 26

1 newton-metre

Question 27

What happens to temperature when work done occurs against frictional forces on an object?

Answer 27

Temperature increases

Question 28

How many forces need to change the shape of an object (by bending, stretching or compressing)?

Answer 28

More than one

Question 29

What has happened if an object has been inelastically deformed?

Answer 29

It doesn’t return to its original shape and length after a force has been removed

Question 30

What has happened if an object has been elastically deformed?

Answer 30

It returns to its original shape and length after a force has been removed

Question 31

What has happened if an object has been elastically deformed?

Answer 31

The extension of an elastic object is directly proportional to the force applied

Question 32

What is the equation that links force, spring constant and extension?

Answer 32

Question 33

When a spring is compressed what does the ‘e’ in ‘F = k e’ represent?

Answer 33

‘e’ would be the compression of the object (the difference between the natural and compressed lengths)

Question 34

Why type of energy is stored when a force does work on a spring?

Answer 34

Elastic potential energy

Question 35

What is distance?

Answer 35

How far an object moves (a scalar quantity) which does not involve direction

Question 36

What is displacement?

Answer 36

Displacement includes both the distance an object moves and the direction (a vector quantity)

Question 37

What does speed not involve?

Answer 37

Direction (it is a scalar quantity)

Question 38

What are typical speed values for someone walking, running and cycling (m/s)?

Answer 38

• Walking 1.5 m/s
• Running 3 m/s
• Cycling 6 m/s

Question 39

Is the speed of sound (and that of the wind) constant?

Answer 39

No – the speed of sound (and that of the wind) can vary

Question 40

What is the typical value for the speed of sound (m/s)?

Answer 40

330 m/s

Question 41

How can distance travelled be calculated?

Answer 41

Question 42

What is the velocity of an object?

Answer 42

Velocity is speed, in a given direction (a vector quantity)

Question 43

Higher Q. How can the motion of an object in a circle be described?

Answer 43

Constant speed but changing velocity

Question 44

If an object is moving in a straight line how can the distance travelled be represented?

Answer 44

Distance-time graph

Question 45

How can the speed of an object be calculated in a distance-time graph?

Answer 45

The gradient

Question 46

Annotate the following distance-time graph:

Answer 46

Question 47

Higher Q. For an accelerating object, how can the speed at a given point be determined?

Answer 47

A tangent can be drawn measuring the gradient of the distance-time graph at that specific time

Question 48

How can acceleration be calculated?

Answer 48

Question 49

What is happening to an object which is slowing down?

Answer 49

It is decelerating

Question 50

Draw a velocity-time graph for two vehicles – one with a constant acceleration and one with a constant acceleration, a constant velocity and a constant deceleration

Answer 50

Question 51

Higher Q. How can the displacement of an object (the distance travelled) be calculated from a velocity-time graph?

Answer 51

The area under a velocity-time graph

Question 52

What is the acceleration of any free-falling object near the Earth’s surface?

Answer 52

9.8 m/s²

Question 53

What initially causes an object falling through a fluid to accelerate?

Answer 53

The force of gravity

Question 54

Why does an object reach terminal velocity?

Answer 54

The resultant force becomes zero

Question 55

What does Newton’s First Law state (for a stationary object)?

Answer 55

If the resultant force is zero a stationary object remains stationary

Question 56

What does Newton’s First Law state (for a moving object)?

Answer 56

If the resultant force is zero a moving object continues to move at the same velocity

Question 57

How can the forces be described for a vehicle moving at a steady speed?

Answer 57

The resistive forces balance the driving force

Question 58

What causes the velocity of an object to change?

Answer 58

The resultant force acting on the object must change

Question 59

Higher Q. What is inertia?

Answer 59

The tendency of objects to continue in their state of rest / uniform motion

Question 60

What is Newton’s Second Law?

Answer 60

The acceleration of an object is proportional to the resultant force acting on the object (and inversely proportional to the mass of the object)

Question 61

What is the equation for Newton’s Second Law?

Answer 61

Question 62

Higher Q. What is inertial mass?

Answer 62

A measure of how difficult it is to change the velocity of an object

Question 63

Higher Q. How can inertial mass ratio be defined?

Answer 63

The ratio of force over acceleration

Question 64

What are typical everyday speeds for cars, trains and planes?

Answer 64

• Car 25 m/s
• Train 55 m/s
• Plane 250 m/s

Question 65

What is Newton’s Third Law?

Answer 65

Whenever two objects interact, the forces they exert on each other are equal and opposite

Question 66

How can the stopping distance of a vehicle be calculated?

Answer 66

The sum of the thinking distance and the braking distance

Question 67

What is thinking distance?

Answer 67

The distance covered during the driver’s reaction time

Question 68

What is braking distance?

Answer 68

The distance covered during the braking force

Question 69

For a given braking force, what does greater speed cause?

Answer 69

A greater stopping distance

Question 70

What are ‘typical’ reaction times?

Answer 70

0.2 s to 0.9 s

Question 71

What can affect a driver’s reaction time?

Answer 71

• Tiredness
• Drugs
• Alcohol

Question 72

What can affect the braking distance of a vehicle?

Answer 72

• Road conditions
• Weather conditions (wet / ice)
• Vehicle conditions (brake / tyre quality etc…)

Question 73

What happens when a force is applied to the brakes of a vehicle (in terms of energy)?

Answer 73

Work done by the friction force between the brakes and wheel reduces kinetic energy of the vehicle (and brake temperature increases)

Question 74

How does increases the speed of a vehicle affect the braking force?

Answer 74

A greater braking force is needed to stop the vehicle in a given distance

Question 75

What does a greater braking force allow?

Answer 75

A greater deceleration

Question 76

What can large decelerations lead to?

Answer 76

Brakes overheating / loss of control

Question 77

How is momentum calculated?

Answer 77

Question 78

What is the conservation of momentum?

Answer 78

In a closed system, the total momentum before an event is equal to the total after an event