9702 Physics June 2025 Question Paper 22

1 short_answer p. 4

1a 2 marks short_answer p. 4 1.4

Table 1.1 lists some physical quantities. Identify with ticks ($\checkmark$) which quantities are vectors and which are scalars.

\textbf{Table 1.1}

\begin{tabular}{|c|c|c|} \hline quantity & scalar & vector \ \hline acceleration & & \ \hline displacement & & \ \hline gravitational potential energy & & \ \hline speed & & \ \hline temperature & & \ \hline \end{tabular}

1b short_answer p. 4

A constant resultant force $F$ acts on a car of mass $m$. The car moves from rest with constant acceleration $a$ along horizontal ground. When the car has displacement $s$, the speed of the car is $v$.

1bi 3 marks long_answer p. 4 5.2

Using the concept of work done on the car, show that the kinetic energy $E_{\text{K}}$ of the car is given by the equation

$$E_{\text{K}} = \frac{1}{2}mv^2$$

1bii 1 mark calculation p. 4 5.2

The mass of the car is $920\text{ kg}$. At time $t = 0$, the car is at rest. At time $t = 5.8\text{ s}$, its velocity is $17\text{ m}\,\text{s}^{-1}$.

Calculate the kinetic energy of the car at time $t = 5.8\text{ s}$.

kinetic energy = \hrulefill J

1biii 3 marks calculation p. 5 5.1

Between time $t = 0$ and time $t = 5.8\text{ s}$, the work done against resistive forces is $4.7 \times 10^4\text{ J}$.

Determine the average output power of the car during this time.

power = \hrulefill \text{ W}

1biv 1 mark long_answer p. 5 5.1

At time $t = 5.8\text{ s}$, the speed of the car becomes constant.

State and explain whether the output power of the car is greater than, less than or the same as the output power just before $t = 5.8\text{ s}$.

2 short_answer p. 6

2a 1 mark short_answer p. 6 4.1

Define the moment of a force about a point.

2b short_answer p. 6

A tree of mass $270\text{ kg}$ grows out of sloping ground and is supported by a post, as shown in Fig. 2.1.

The ground applies a total force $R$ on the tree at point Q. The centre of gravity of the tree is a horizontal distance of $1.2\text{ m}$ from Q. The post applies a force $F$ of $1800\text{ N}$ perpendicular to the line PQ. The line of action of $F$ passes through point P at an angle $\theta$ to the vertical. P is a horizontal distance of $1.6\text{ m}$ from Q. The tree is in equilibrium and all forces act on the tree in the same plane.

2bi 3 marks calculation p. 6 4.1

By taking moments about point Q, show that $\theta$ is $25^\circ$.

2bii 2 marks short_answer p. 7 4.2

On Fig. 2.2, draw a labelled scale vector triangle to represent the forces acting on the tree. The weight of the tree has been drawn to scale.

2biii 2 marks calculation p. 7 4.3

The tree exerts a pressure of $150\text{ kPa}$ on the top of the post.

Determine the surface area of the tree in contact with the post.

area = \hrulefill $\text{m}^2$

3 short_answer p. 8

Two progressive water waves X and Y travel along a straight line from point A to point B. The variation of displacement of the waves with distance from A at an instant in time is shown in Fig. 3.1.

3a 1 mark short_answer p. 8 7.1

State the amplitude of wave X.

amplitude = \hrulefill $\text{cm}$

3b short_answer p. 8

Both waves have frequency $16\text{ Hz}$.

3bi 2 marks calculation p. 8 7.1

Determine the speed of wave X.

speed = \hrulefill $\text{m}\,\text{s}^{-1}$

3bii 1 mark long_answer p. 8 8.3

State and explain whether X and Y are coherent.

3c 2 marks short_answer p. 9 8.1

Wave X and wave Y superpose to form a resultant wave.

On Fig. 3.2, sketch the variation of displacement of the resultant wave with distance from A at the instant of time shown in Fig. 3.1.

3d 2 marks calculation p. 9 7.1

The intensity of wave X is $I_X$. The intensity of wave Y is $I_Y$.

Use Fig. 3.1 to determine the ratio $\frac{I_X}{I_Y}$.

ratio = \hrulefill

4 short_answer p. 10

A small ball is dropped from rest from height $h_1$ above the ground and falls vertically downwards. The ball collides with the ground and bounces back vertically upwards, reaching a maximum height $h_2$. Fig. 4.1 shows the ball just before and just after hitting the ground.

The ball has mass $0.25\text{ kg}$ and is in contact with the ground for a time of $0.18\text{ s}$. Just before the ball hits the ground, it has speed $5.2\text{ m}\,\text{s}^{-1}$. Just after it leaves the ground, it has speed $3.6\text{ m}\,\text{s}^{-1}$. Air resistance acting on the ball is negligible.

4a 1 mark long_answer p. 10 3.3

State and explain whether the collision is elastic or inelastic.

4b short_answer p. 10

(no root text)

4bi 2 marks calculation p. 10 3.1

Calculate the change in momentum of the ball during the collision with the ground.

change in momentum = \hrulefill $\text{kg}\,\text{m}\,\text{s}^{-1}$

4bii 2 marks calculation p. 10 3.1

Determine the average force on the ball during the collision with the ground.

force = \hrulefill $\text{N}$

4c 3 marks calculation p. 11 5.2

Calculate the ratio $\frac{h_2}{h_1}$.

ratio = \hrulefill

5 short_answer p. 12

5a 1 mark short_answer p. 12 6.1

Define the Young modulus.

5b short_answer p. 12

A wire of unstretched length $0.81\text{ m}$ is made of a metal with Young modulus $95\text{ GPa}$. The wire obeys Hooke's law and has a constant cross-sectional area. Fig. 5.1 shows the force–extension graph for the wire.

5bi 3 marks calculation p. 12 6.1

Determine the cross-sectional area of the wire.

area = \hrulefill $\text{m}^2$

5bii 3 marks calculation p. 13 6.2

The extension of the wire is initially $2.0 \times 10^{-3}\text{ m}$.

Determine the work done to increase the extension of the wire to $3.0 \times 10^{-3}\text{ m}$.

work done = \hrulefill \text{ J}

6 short_answer p. 14

6a 1 mark short_answer p. 14 9.2

Define electric potential difference across a component.

6b short_answer p. 14

A circuit contains four resistors and a battery of electromotive force (e.m.f.) $8.0\text{ V}$ with negligible internal resistance. When the variable resistor has resistance $R$, the currents in the circuit are $0.030\text{ A}$, $I_1$ and $I_2$, as shown in Fig. 6.1.

6bi 2 marks calculation p. 14 9.1

Determine the charge passing through the battery in a time of $4.0\text{ minutes}$.

$\text{charge} = \hrulefill \text{ C}$

6bii 2 marks calculation p. 14 10.2

Calculate $I_1$.

$I_1 = \hrulefill \text{ A}$

6biii 1 mark calculation p. 15 10.2

Calculate $I_2$.

$I_2 = \hrulefill \text{ A}$

6biv 2 marks calculation p. 15 10.2

Determine $R$.

$R = \hrulefill \ \Omega$

6c 2 marks long_answer p. 16 10.3

The variable resistor in (b) is fitted with a scale so that its resistance can be accurately determined. The resistor of resistance $240\ \Omega$ is now replaced by a new resistor X of unknown resistance. A galvanometer is connected as shown in Fig. 6.2.

Fig. 6.2

With reference to ratios of resistances, explain how this circuit can be used to determine the resistance of X.

7 short_answer p. 17

(no root text)

7a 1 mark short_answer p. 17 11.2

State what is meant by a fundamental particle.

7b short_answer p. 17

A nucleus X has 14 nucleons and $p$ protons. The ratio of charge to mass for nucleus X is $4.1 \times 10^7 \text{ C kg}^{-1}$.

7bi 3 marks calculation p. 17 11.1

Determine $p$.

$p =$ \hrulefill

7bii 3 marks short_answer p. 17 11.1

Nucleus X undergoes $\beta^-$ decay to form nucleus Z.

Complete the equation representing this decay.

$$\text{}^{14}_{\dots\dots}\text{X} \rightarrow \text{}^{\dots\dots}_{\dots\dots}\text{Z} + \text{}^{\dots\dots}_{\dots\dots}\dots\dots + \text{}^{\dots\dots}_{\dots\dots}\dots\dots$$

7c 2 marks long_answer p. 17 11.1

A sample of a radioactive substance emits particles that are positively charged and have a continuous range of kinetic energies.

State and explain whether the nuclei in the sample are undergoing $\alpha$-decay, $\beta^+$ decay or $\beta^-$ decay.

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